KR101854136B1 - Corrugated Deck Having Truss Girder - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compression and tension-strengthening truss girder integrated deck, and more particularly, to a compression and tension-reinforcement truss girder which constitutes a tensile reinforcement in the interior of a slim-shaped deck deck and constitutes a truss girder having a compression- The present invention relates to an integrated deck.
In a preferred embodiment of the present invention, a flat plate of a predetermined size is formed by bending, and a plurality of lower bones are formed in the entire length direction so as to protrude downward with respect to a plane portion, and both end portions in the width direction are bent, And a slab-shaped deck deck is formed at a flat portion on both sides in the width direction of each of the lower slabs to protrude upward to form a rib; A compression reinforcement member having a predetermined length formed of a steel material, a lower end portion formed as a pair spaced apart from the lower portion of the compression reinforcement member, and a compression reinforcement member connected to the compression reinforcement member at both sides in the width direction of the compression reinforcement member, A truss girder made of a lattice material bent outward at the lower end to form a foot portion, the foot portion of the lower portion of the lattice material being coupled to the ribs on both sides in the width direction of the lower trough; And a tensile reinforcement rope that is fixed to the center of the lower crest by the fixing attachment member and is formed in the longitudinal direction inside the lower crest of the deck so as to be positioned below the flat portion.

Description

[0001] DESCRIPTION [0002] Corrugated Deck Having Truss Girder [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compression and tension-strengthening truss girder integrated deck, and more particularly, to a compression and tension-reinforcement truss girder which constitutes a tensile reinforcement in the interior of a slim-shaped deck deck and constitutes a truss girder having a compression- The present invention relates to an integrated deck.

Steel structures and steel-reinforced concrete structures with excellent durability and earthquake resistance are mainly adopted as the structural form of high-rise buildings. In such high-rise buildings, deck plates are generally used for floor slab systems because of shortening of air and reduction of labor costs. Truss flat decks with a truss type girder and a flat type deck plate (flat flat deck plate) were developed. The truss girder was able to receive a temporary load by the truss girder, .

In this case, the flat type deck plate is used as a mold plate when pouring the concrete of the bottom slab by using a thickness of 0.5 mm, but it is not a factor to directly resist the hypothetical load, that is, the construction load like a truss girder.

However, in the case of such a truss flat deck, it is impossible to apply to the long span due to the problems such as tearing of the concrete without being able to withstand the concrete piling load. In order to overcome this problem, if the height of the truss girder is increased, As the amount of concrete increases, the self weight is increased, the construction load is increased, and the thickness of the slab is thickened, so that the stratification is increased and the economical efficiency is lowered.

As a background of the present invention, there is Korean Patent Registration No. 1136582 entitled " Welded Reinforced Truss Integral Type Deck Plate "(Patent Document 1). In the background art, a unit unit composed of a top plate, a trapezoidal cross section as a whole, a side plate bent downwardly at both ends in the width direction of the top plate, and a bottom plate bent horizontally at an end portion in the width direction of each side plate A bone deck plate repeatedly formed in a transverse direction and having a mountain portion formed by an upper plate and a side plate, and a valley portion formed by the lower plate and the side plate continuously; A pair of lower reinforcing bars provided at the bottom of the upper reinforcing bars and spaced apart from each other below the upper reinforcing bars, and a plurality of lower reinforcing bars disposed along the longitudinal direction of the upper reinforcing bars and the lower reinforcing bars, A plurality of rebar trusses comprising a pair of web bars; And at the ends of the first and second screw rods and the first and second screw rods which are installed at regular intervals along the longitudinal direction of each of the reinforcing bar trusses and are screwed on both sides of the adjusting nut and the adjusting nut, Welded reinforced concrete truss-integrated deck plate " comprising a plurality of joints each composed of a tightly coupled plate and extending a gap between lower reinforcing bars.

However, the background art can not increase the buckling strength with respect to the compressive force of the upper element, so that it can not be applied to an elongated span, and it has to be mounted on the upper part of the beam at the side of the beam.

Korean Patent No. 1136582 entitled "Welded Reinforced Truss Integral Type Deck Plate"

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a truss girder having a tensile reinforcement inside a thin deck deck, Reinforced truss girder integrated deck which can be applied to an elongated span without increasing the height of the truss girder by increasing the buckling strength with respect to the compressive force of the tension girder, .

A plurality of lower corrugations are formed in a longitudinal direction so as to protrude downward with respect to a plane portion. The deck connection portions are formed by bending both ends in the width direction and forming a deck connection portion along the longitudinal direction. A slim-shaped deck deck having protrusions protruding upward to form ribs on both sides in the width direction of the lower bone; A compression reinforcement member having a predetermined length formed of a steel material, a lower end portion formed as a pair spaced apart from the lower portion of the compression reinforcement member, and a compression reinforcement member connected to the compression reinforcement member at both sides in the width direction of the compression reinforcement member, A truss girder made of a lattice material bent outward at the lower end to form a foot portion, the foot portion of the lower portion of the lattice material being coupled to the ribs on both sides in the width direction of the lower trough; And a tensile reinforcement rope fixed to a center portion of the lower bone by a fixing attachment member and longitudinally formed inside the lower bone of the deck so as to be positioned at a lower portion with respect to the flat portion. Deck.

The present invention also provides a truss girder integrated deck for a compression and tension reinforcement, characterized in that the thin deck deck is formed with a buckling portion for bending the lower trough in the direction of the plane portion to a point where the trough is inserted at a predetermined distance from both ends in the longitudinal direction, do.

Also, the ribs are formed to be inclined at a predetermined angle from the widthwise center of the lower crest to the outward direction, thereby providing a truss girder integrated deck with a compression and tensile reinforcement.

Also, it is desirable to provide a compression and tension-strengthening truss girder integral type deck characterized in that two compression strengthening members are vertically or horizontally connected to each other in a juxtaposition.

Also, it is desirable to provide a compression and tension-strengthening truss girder integrated deck characterized in that the compression strengthening member is a polygonal or circular steel pipe having an empty interior.

Also, it is desired to provide a compression and tensile reinforced truss girder integrated deck characterized in that the compression reinforcement member is filled with high-strength mortar or concrete.

Also, it is desirable to provide a compression and tension-strengthening truss girder integrated deck characterized in that the compression reinforcing member is cut at a central portion of an upper portion in the width direction with a predetermined width.

The fixing member is formed to have the same cross section as the cross section of the lower valley and has a coupling groove formed to a predetermined height from the central portion in the width direction of the lower end portion to a fixed height. Tension reinforced truss girder integrated deck.

Further, a support portion further projecting from the upper end of the fixed attachment member to the upper portion of the horizontal plane is formed so that the upper surface of the support portion closely supports the lower portion of the foot, thereby providing a truss girder integral deck with compression and tensile strength.

The fixed attachment member is formed of a member having a U-shaped section and has a seating groove formed at a predetermined interval at an upper portion thereof. The lower surface of the fixed attachment member is coupled with a tensile reinforcement bar, And a truss girder integral type deck characterized in that it is provided with a compression and tensile reinforcing truss girder.

Wherein the upper end portion is coupled to the lower surface of the compression reinforcement member and the lower end portion is formed at both longitudinal end portions of the compression reinforcement member joined to the upper surface of the planar portion of the slender deck deck. Truss girder integrated deck.

The point reinforcing member is composed of a horizontal mounting portion, a supporting portion extending downward from both sides of the mounting portion, and a pair of coupling portions extending in a direction perpendicular to the mounting portion at a lower end of the supporting portion, Reinforced truss girder integrated deck, which is coupled to the lower surface of the reinforcing member, and the ends of the tensile reinforcement rods are fitted between the pair of engaging portions.

Also, a transverse bridge is coupled to an upper portion of the lower crest so as to connect the upper surface of the lower crest in the transverse direction, thereby providing a truss girder integrated deck with a compression and tension reinforcement.

A filler made of a porous organic or inorganic material is formed between the lower bone and the lower bone on the basis of the plane portion, and a finishing plate is attached to a lower portion of the lower face of the lower bone. To provide an integrated deck.

The compression and tension-strengthening truss girder integral deck comprises a tensile reinforcement in the interior of the slim-type deck deck, and a truss girder in which the compression reinforcement member is formed on the upper portion. It is possible to apply to the long span without increasing the height of the truss girder by increasing the buckling strength with respect to the compressive force and to have a very useful effect that the load during the construction can be shared among the tensile reinforcement rods.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
1 is a partially exploded perspective view of a compression and tension-strengthening truss girder integral deck of the present invention.
Fig. 2 is a cross-sectional view of Fig. 1 above.
FIG. 3 is a longitudinal sectional view of the above-mentioned FIG. 1;
4 is a cross-sectional view of various embodiments of the compression reinforcement member of the truss girder of the present invention.
5 is a perspective view showing various embodiments of the fixing attachment member of the present invention.
Figures 6-8 illustrate various embodiments of the transverse bridge of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

Hereinafter, the technical structure of the present invention will be described in detail with reference to the preferred embodiments.

1 is a partially exploded perspective view of a compression and tension-strengthening truss girder integral deck of the present invention.

1, the compression and tension-strengthening truss girder integral type deck 1 of the present invention includes a tensile reinforcement 1 and a tensile reinforcement 2 disposed inside the lower trough 12 so as to be positioned below the flat portion 11 of the slim- (40), and the truss girder (20) constituted by the compression reinforcing member (21) is formed on the upper part.

FIG. 2A is a cross-sectional view of FIG. 1, and FIG. 3 is a longitudinal sectional view of FIG.

The slim-type deck deck (10) of the present invention is formed by bending a plate material having a predetermined length and width, and a lower crest (12) is formed so as to be recessed to open the upper part.

The lower bones 12 are formed in the entire longitudinal direction so as to protrude downward with respect to the flat surface portion 11.

The lower trough 12 has an inverted trapezoidal shape having a horizontal portion 12a having a lower horizontal section and a side wall portion 12b extending upward from both widthwise sides of the horizontal portion 12a, The tension force acting on the truss girder 20 is applied to the tensile reinforcement rope 40 fixed to the fixed fastening member 50 while the fastening force is increased so that the fixed fastening member 50 is not pulled out to the upper portion of the lower trough 12. [ So that the tensile resistance performance of the slim-shaped deck deck 10 is increased.

The cross section of the lower trough 12 may be formed by bending into a trapezoidal shape or various other polygonal shapes as shown in FIG. 2D, in addition to the inverted trapezoidal shape as in the above embodiment.

The lower bones (12) have a plurality of spaced apart portions (17) spaced in the width direction.

When the concrete is laid on the upper surface of the slim-shaped deck 10, the uppermost surface of the slim-like deck 10 is filled into the lower deck 12 as well as the upper surface thereof. So that the construction resistance performance of the slim-type deck deck 10 is improved, and the present invention can be applied to an elongated span.

Further, ribs 15 are formed on the flat portions 11 on both sides in the width direction of the lower trough 12 so as to protrude upward.

The rib 15 may be formed immediately adjacent to the lower trough 12 and may be formed so as to protrude upward from the flat portion 11 at a distance from the lower trough 12, So that the foot portion 231 of the main body 20 is mounted to be engaged.

2B and 2C are views showing another embodiment of FIG. 2A.

The ribs 15 may protrude vertically upwards or may be formed at an angle of a predetermined angle from the center in the width direction of the lower trough 12 to the outside as shown in FIG. 2B.

In order to engage with other decks, the slim-shaped deck deck 10 may have deck connecting portions 14a and 14b formed along the longitudinal direction by bending both ends in the width direction.

The deck connecting portions 14a and 14b are formed in such a manner that one deck connecting portion 14a is folded in three stages and the other deck connecting portion 14b is folded in one stage, The deck connecting portions 14a and 14b can be applied to various forms in the art of the deck plate. The deck connecting portions 14a and 14b can be applied to the horizontal portion 12a of the lower trough 12 and / Dovetail grooves of various known shapes can be formed on the planar portion 11 between the valley 12 and the adjacent lower valley 12.

A tensile reinforcement rope 40 made of a metal material such as a reinforcing bar, a wire or a round bar or a composite material (FRP, high-performance plastic) is formed in the longitudinal direction of the lower trough 12 of the slim- , So that the tensile resistance can be increased.

The tensile reinforcement rope 40 maintains a constant distance from the horizontal portion 12a of the lower trough 12 and the torsional reinforcement rope 40 is integrally formed with the slender trough deck 10 against lateral torsion of the tensile reinforcement rope 40 in the lower trough 12. [ One or more fixed attachment members 50 may be provided at predetermined intervals in the longitudinal direction of the lower trough 12 and the tensile reinforcement rods 40 may be coupled to the fixed attachment member 50. [

The tensile reinforcement rope 40 is positioned at a predetermined height below the flat portion 11 of the slim-like deck 10 at the center in the width direction of the lower trough 12 by the fixing attachment member 50, 12) is effective for flexural torsion and bending performance.

2, the fixed attachment member 50 is formed to have the same cross-section as the end surface of the lower trough 12 and to have a coupling groove 51 having a predetermined size from the center in the width direction of the lower end to a predetermined height, The tensile reinforcement rods 40 may be fixed to the coupling grooves 51 and may be made of various materials such as a metal material, a nonmetal material, a synthetic resin material, and the like. At this time, the engaging groove 51 formed in the fixed attachment member 50 may be formed to be vertically or constantly inclined so that the tensile reinforcement rope 40 can be easily inserted.

The pulling force of the tensile reinforcement rope 40 inserted in the engaging groove 51 of the fixed attachment member 50 can be adjusted to a predetermined value by forming the engaging groove 51 from the lower end to the upper end of the fixed attachment member 50 The upper surface of the support portion 52 is formed to be lower than the lower portion of the foot portion 231 The tensile reinforcement rope 40 is engaged by using the fixed attachment member 50 so that the load during the operation applied to the upper portion of the slim-shaped deck 10 is transmitted to the tensile reinforcement rope 40 ) To the user.

5 is a perspective view showing various embodiments of the fixing attachment member of the present invention.

5B, a member having a U-shaped cross-section such as a channel may be provided on the lower trough 12, As shown in FIG. 5 (a), a through hole may be formed so as to penetrate a member having a U-shaped cross-section such as a channel so that the tensile reinforcement rope 40 may penetrate It may be fixed through the sphere.

In particular, as shown in FIG. 5 (c), it is formed of a member having a U-shaped cross-section, a seating groove 56 is formed at an upper portion at a predetermined interval, a tensile reinforcement rope 40 is coupled to a lower surface, The lower current 22 is seated in the upper seating groove 56 so that the load acting on the upper portion of the slim-shaped deck 10 can be sufficiently transmitted to the tensile reinforcement rods 40 through the truss girder 20 Can ...

The present invention is configured such that the lower bones 12 are formed so as to protrude downward with respect to the plane portion 11 as described above. However, when a certain length of both ends in the longitudinal direction of the slim- 12 are bent in the direction of the flat surface portion 11 and the end portions thereof are closed in the longitudinal direction so as to form the dagger portion 13 in the form of a dapped end so that when the ends of the lower trough 12 The height is accommodated in the dancing of the beam, so that even in the case of the long span, it is possible to prevent the problem of increase in the height of the slab, such as thickening of the slab.

At this time, the predetermined length of the lengthwise ends of the slenderly-shaped golf deck 10 is set such that the lower slivers 12 are pressed and brought into complete contact with the flat surface portion 11, A dapped end may be formed at the point so that the cross section of the lower trough 12 is abruptly increased and the inclined surface 131 may be formed so as to gradually change the cross section, . In addition, a space for installing a common facility such as a piping or an electrical installation can be utilized as a space in the lower portion of the tail portion 13. [

The tension reinforcement rope 40 is disposed inside the lower trough 12 so that the end portion of the tensile reinforcement rope 40 is bent so that the ridge portion 13 is formed, The lengthwise ends of the tensile reinforcement rods 40 may be positioned and engaged.

The truss girder 20 is formed to have a shape similar to that of a general truss girder made up of lattice materials connecting the current, the lower, and the upper and lower currents. In the present invention, in particular, It is possible to use a compression reinforcement member 21 having a certain length even in an elongated span by using a steel material to increase the compressive force and the buckling strength.

The compression reinforcement member 21 may be formed of a tubular body such as a polygonal shape such as a trapezoid, a quadrangle, or the like, or a circular or elliptic shape.

4 is a cross-sectional view of various embodiments of the compression reinforcement member of the truss girder of the present invention.

As shown in FIG. 4 (a), the compression reinforcement member 21 may be a round bar, a square bar, or the like, and the compression reinforcement members 21 may be vertically or horizontally arranged in parallel As shown in FIG. 4 (c), the compression strengthening member 21 may be formed as an angular or circular steel pipe having an empty interior to increase the size of the cross section. 4 (d), the compression strengthening member 21 may be filled with high-strength mortar or concrete C to enhance the rigidity when it is an angular or circular steel pipe with an empty interior, The compression reinforcing member 21 may be cut at a central portion of the upper portion in the width direction so as to have a constant width so that the charging of the high strength mortar or concrete C is facilitated.

1 and 2, the lower case 22 is formed as a pair spaced apart from the lower portion of the compression reinforcement member 21 by a predetermined distance, and the compression reinforcement member 21 And a foot portion 231 is formed on the lattice material 23 so as to be bent outward at the lower end.

Such a truss girder 20 is joined to the ribs 15 on both sides in the width direction of the lower trough 12 by a variety of known methods such as welding by the foot portion 231 at the lower end of the lattice material 23.

Figures 6-8 illustrate various embodiments of the transverse bridge of the present invention.

The transverse bridge 70 may be formed on the upper portion of the opening S of the lower trough 12 to connect the upper surfaces of the lower trough 12 to prevent the lower trough 12 from being opened.

6B is a cross-sectional view taken along the line A-A in FIG. 6A.

As shown in FIGS. 6A and 6B, the transverse bridge 70 is disposed on the horizontal surface 11 on both sides of the lower trough 12 by arranging a plate of a predetermined size across the upper portion of the lower trough 12 in a transverse direction Welding, or the like. As shown in FIG. 7, it may be formed of various wire rods such as a steel bar, a square bar, etc., and the upper portion of the lower rib 12 It may be formed so as to traverse in a zigzag manner.

At this time, the transverse bridge 70 may be formed so as to traverse only the upper opening S of one lower trough 12, as in the illustrated embodiment, and two or more lower troughs 12 As shown in FIG.

The tension reinforcement rope 40 may be coupled to the lower portion of the transverse bridge 70 thus configured to further improve the tensile resistance.

In addition, buckling and point shear forces of the truss girder 20 can be reinforced at the end portions of the branch reinforcement member 30 by being formed at both longitudinal ends of the compression reinforcement member 21. [

The point reinforcing member 30 may be formed in various shapes such as a triangular shape by forming metal or synthetic resin such as a wire or a sheet material so that the upper end of the point reinforcing member 30 is coupled to the lower surface of the compression reinforcing member 21 And the lower end thereof is engaged with the upper surface of the planar portion 11 of the slim-shaped deck 10.

Particularly, as shown in Figs. 1 and 3, the branch reinforcing member 30 includes a horizontally formed mounting portion 31, a support portion 32 extending downward from both sides of the mounting portion 31, And a pair of engaging portions 33 extending in a direction perpendicular to the mounting portion 31 at a lower end of the mounting portion 31. The mounting portion 31 is coupled to the lower surface of the compression reinforcing member 21, The ends of the tensile reinforcement rods 40 can be fitted between the coupling portions 33 of the pair.

2C, a filling material 80 made of a porous organic or inorganic material is formed between the lower bone 12 and the lower bone 12 on the basis of the plane portion 11, A finishing plate 81 may be attached to a lower portion of the lower surface of the base plate 12.

The filling material 80 is made of styrofoam or glass wool or a porous lightweight organic or inorganic material and is formed between the lower bone 12 and the adjacent lower bone 12 on the basis of the plane portion 11 It is possible to provide a sound absorbing function, a heat insulating function, and a fireproof function.

The finishing plate 81 may be made of a finishing perforated plate manufactured to have a predetermined width and may be manufactured so as to cover the lower portion of two or more lower corrugations 12, Such as a screw, a screw, a hanger bolt, and a welding method.

The truss girder integral type deck of the present invention as described above can form a tensile reinforcement in the interior of the slim-type deck deck and a truss girder in which the compression reinforcement member is formed on the upper part, It is possible to apply to the long span without increasing the height of the truss girder by increasing the buckling strength with respect to the compressive force of the upper element, and to have a very useful effect that the load during the construction can be shared among the tensile reinforcement rods.

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 in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

1: Compression and tension reinforcement Truss girder integral deck
10: Slim type deck
11:
12: Lower bone
13:
14a, 14b: Deck connection
15: rib
20: Truss girder
30: Branch reinforcing member
21: Compression reinforcing member
22: Height current
23: Lattice material
40: tensile rebar
50: Fixed mounting member
51: Coupling groove
70: transverse bridge
80: Filler

Claims (14)

A plurality of lower corrugations 12 are formed in the entire longitudinal direction so as to protrude downward with respect to the flat surface portion 11, and both ends in the width direction are bent to form a deck connection portion The ribs 15 protrude upward from the flat portions 11 on both sides in the width direction of the lower troughs 12 to form the lower troughs 14a, 12) is bent in the direction of the flat surface portion (11) to form a step portion (13) for closing the longitudinal direction end portion;
The compression reinforcement member 21 has a constant length formed of a steel material. The compression reinforcement member 21 has a pair of lower ends 22 spaced apart from the compression reinforcement member 21 by a predetermined distance. And a lattice material 23 which is connected to connect the compression reinforcement member 21 and the lower current 22 and which is bent outward at the lower end to form a foot portion 231. The lattice material 23 has a lower foot portion 231 (20) coupled to ribs (15) on both sides in the width direction of the lower trough (12);
The tensile reinforcement bars are formed in the longitudinal direction inside the lower trough 12 of the deck 10 so as to be positioned at the lower portion with respect to the flat surface portion 11 and fixed to the central portion of the lower trough 12 by the fixed attachment member 50. [ (40)
The upper end portion is coupled to the lower surface of the compression reinforcing member 21 and the lower end portion is connected to the upper surface of the flat surface portion 11 of the slenderly shaped deck 10 by the length of the compression reinforcing member 21 Direction,
The point reinforcing member 30 includes a horizontally formed mounting portion 31, a support portion 32 extending downward from both sides of the mounting portion 31 and a support portion 32 extending downward from the mounting portion 31 at right angles And a pair of engaging portions 33 extending in the direction of the arrow A,
Is coupled to the lower surface of the compression reinforcing member (21) at the upper portion of the mounting portion (31)
And an end of the tensile reinforcement rope (40) is fitted between the pair of engaging portions (33). delete The method according to claim 1,
Wherein the ribs (15) are formed so as to be inclined at a certain angle in the outward direction from the center in the width direction of the lower trough (12). The method according to claim 1,
The compression and tensile reinforcing truss girder integral type deck as claimed in claim 1, wherein the compression strengthening members (21) are vertically or horizontally joined to each other. The method according to claim 1,
Wherein the compression strengthening member (21) is a polygonal or circular steel pipe with an empty interior. The method of claim 5,
Characterized in that the compression strengthening member (21) is filled with high-strength mortar or concrete inside the truss girder integral deck. The method of claim 5,
The compression and tensile reinforcing truss girder integrated deck according to any one of claims 1 to 3, wherein the compression reinforcing member (21) is cut at a central portion of an upper portion in the width direction at a predetermined width. The method according to claim 1,
The fixed attachment member 50 is formed to have the same cross-section as the end surface of the lower trough 12 and has a coupling groove 51 having a predetermined size from the center in the width direction of the lower end to a predetermined height,
And the tension reinforcement rope (40) is fitted and fixed to the coupling groove (51). The method of claim 8,
A support portion 52 further projecting from the upper end of the fixed attachment member 50 to the upper portion of the horizontal plane 11 is formed,
So that the upper surface of the support portion (52) closely supports the lower portion of the foot portion (231). The method according to claim 1,
The fixed attachment member 50 is formed of a member having a U-shaped cross section and has a seating groove 56 formed at a predetermined interval thereon,
Wherein the lower surface is formed such that the tension reinforcement rope (40) is engaged and the lower seating (22) is seated in the upper seating groove (56). delete delete The method according to claim 1,
And a transverse bridge (70) is coupled to the upper portion of the lower trough (12) so as to laterally connect the upper surface of the lower trough (12). The method according to claim 1,
A filling material 80 made of a porous organic or inorganic material is formed between the lower bone 12 and the lower bone 12 with respect to the plane portion 11,
And a finishing plate (81) is attached to a lower portion of the lower surface of the lower trough (12).

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