KR101531690B1 - Grid type rib deck , grid type arch rib deck and the construction method therewith - Google Patents

Abstract

Provided are a lattice-type rib deck, a lattice-type arch rib deck, and a construction method thereof capable of improving a load supporting capacity to effectively control tensile cracks by effectively supporting girders and beams of a bridge and adjoining decks. The lattice-type rib deck includes outer haunch units formed to be integrated with both lengthwise ends and both breadthwise outer ends of a body unit and a lattice-type rib integrally formed between the outer haunch units to obtain recessed internal spaces (S) partitioned due to the block-out bottom surface of the body unit. The lattice-type arch rib deck includes lattice-type arch ribs integrally formed between the outer haunch units.

Description

Technical Field [0001] The present invention relates to a grid type rib deck, a grid type arch rib deck,

The present invention relates to a lattice type rib deck, a lattice type arch rib deck and a construction method thereof. More particularly, to a lattice type rib deck, a lattice type arch rib deck, and a method of constructing the same which can effectively support tensile cracks by enhancing load supporting ability by effectively supporting the girders, beams and adjacent decks of bridges.

Figures 1a and 1b illustrate deck and constructor attempts for a conventional concrete slab.

The concrete slab deck 12 is formed by forming the panel main plate 13 in a rectangular shape and integrally forming a reinforcement hatch 14 on the outer edge of the panel main plate 13. [

Accordingly, the concrete slab deck 12 is formed so that four sides of the panel main plate 13 are supported by the reinforcing hammers 14 so as to have an inner hollow.

A plurality of reinforcement bars 18 and a main bar 16 are disposed in the panel main plate 13 and a plurality of shear connection members 20 and 20 are formed in the main bar 16 and the reinforcement bar 18, ) Is installed.

Accordingly, since the inner hollow by the reinforcement hatch 14 is an empty space, it is possible to reduce the weight of the concrete slab deck 12 and to secure the rigidity of the concrete slab deck 12 by the reinforcing hammock However, as the lateral spacing between the girder and the girder increases as in the case of a steel box girder, it is not sufficient to effectively reinforce the concrete slab deck 12, so tensile cracks are generated in the lower portion of the concrete slab deck 12, There is a problem that management is not easy.

Therefore, the method of increasing the thickness of the concrete slab deck 12 or increasing the amount of laying of the main rope 16 and the reinforcing bar 18 is a factor that increases the weight of the concrete slab deck 12 Therefore, it is not structurally effective, and the manufacturing cost is inevitably increased.

Also, in the case of the conventional concrete slab deck 12, as shown in FIGS. 1B and 1C, the upper part of the connecting portion contacting in the longitudinal direction causes a problem such as reflection cracks due to a sectional loss (the thickness of the slab concrete becomes relatively thick) And a tensile crack is generated in the lower portion of the panel main plate 13 when the thickness of the panel main plate 13 for securing the slab thickness is limited. These tensile cracks were inevitably a problem to be solved especially in the girder bridge construction by the small number of molds.

Accordingly, the present invention can solve the problem of tensile cracking by maximizing the load distribution effect by allowing the four sides of the body to be supported at the time of installation while minimizing the self weight increase factor by optimizing the sectional shape while having a limited body thickness. The present invention also provides a grid type rib deck, a grid type arch rib deck, and a method of constructing the same.

To achieve the above object,

First, the deck of the present invention is composed of a rectangular shaped body and four outer side portions, and the deck is formed such that the long side extended length is larger than the short side extended length. At this time, the outer spiral portion is formed as a spiral portion formed by an outer downward slope portion and an inner downward slope portion, and the bottom face is installed around the structure (a girder, a cross beam, and an outer spatter portion in the other long side direction of the adjacent grid type rib deck).

At this time, the inner side of the outer side of the four sides is blocked so that the bottom of the body is blocked out to secure a groove-like inner space, wherein the inner space is formed integrally with the outer wedge portion. Therefore, the deck of the present invention is referred to as a grid-shaped rib deck in the sense that the outer half portion and the grid-shaped ribs of four sides are formed.

Furthermore, since the length in the long-side direction is made longer between the upper surfaces of the girders having the larger lateral spacing due to the minority mold, the lattice ribs according to the present invention can be formed into an arch shape (latticed arch rib) in the extending direction. The present invention will be referred to as a grating type arch rib deck.

Therefore, the weight of the deck through the securing of the inner space can be reduced, and the load acting on the deck can be dispersed to the outer side of the four sides through the lattice type rib and the lattice type arch rib. Accordingly, it is possible to secure a more effective load-bearing performance and to suppress the generation of tensile cracks without increasing the thickness of the body portion.

Second, the inner reinforcing bars are arranged in the body of the lattice type rib decks and the lattice type arch rib decks of the present invention, and the lattice reinforcing bars bound to the inner reinforcing bars are protruded to the upper surface of the body portion to secure the composite performance with the slab concrete .

Thirdly, in the lattice type rib deck and the lattice type arch rib deck of the present invention, the outer side of the four sides of the bridge deck is supported on the upper side of the girder which is adjacent to the transversely opposite side in the both side direction, The tooth portion is supported on the upper surface of the cross beam of the bridge, and the outer half portion in the other long side direction side is supported by the step portions mutually with the one side long side outer half portion of the adjacent grid type rib deck.

Therefore, the lattice type rib deck and the lattice type arch rib deck of the present invention according to the present invention can be stably mounted, and the cross-sectional loss is minimized at the connection portion of the adjacent outer long- So that cracks and the like do not occur.

Fifthly, lattice reinforcement is adjacent to each other in the long side direction adjacent to each other. In order to compensate the cross-sectional loss of the connection part between the outer side and the outer side of the lattice reinforcement, .

The lattice type rib decks and the lattice type arch rib decks according to the present invention can solve quality control problems such as tensile cracks and reflection cracks even if they have the same thickness (for example, 60 to 90 mm) It is easy to carry and install, and more stable support can be installed, so that it is possible to provide an efficient and economical lattice type rib deck, a lattice type arch rib deck, and a construction method thereof.

FIGS. 1A and 1B show a conventional concrete slab deck and construction company,
FIG. 1C is an exemplary view showing the generation of semi-regular heat of a conventional concrete slab deck,
FIGS. 2A and 2B are top and bottom perspective views of a lattice type rib deck according to the present invention,
FIG. 2c is a top and bottom perspective view of a grating arch rib deck according to the present invention, FIG.
FIGS. 3A and 3B are a perspective view and a cross-sectional view of a lattice type rib deck according to the present invention,
FIGS. 4A, 4B and 4C are views showing the construction of a grid-shaped rib deck according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Grid rib deck 100]

2A and 2B are a top perspective view and a bottom perspective view and a cross-sectional view of a latticed rib deck 100 according to the present invention.

The lattice rib deck 100 of the present invention includes a body 110, a four-side outer half portion 120, a lattice rib 130, an inner reinforcing bar 140, and a shear connector 150 It is made of reinforced concrete using a mold.

2A, it can be seen that the body 110 has a rectangular shape and is formed such that the long side extension length in the longitudinal direction (the long side direction) is larger than the short side extension length (the right side direction in the long side direction) . At the four sides of the long side and the short side of the body 110, four outer sides are formed integrally with the body. That is, it can be seen that the four sides (outer peripheral end portions of the body portion) in the long side direction and the short side direction of the body portion are formed to be inclined downwardly by the outer side half portion 120.

2B, the outer hanging part 120 is formed as an outer lower downward slope part 121 and an inner downward slope part 122 and is integrally formed with the body part 110, , And is mounted so as to be seated and supported on the outer half portion in the adjacent long side direction.

At this time, the outer half portion 120 of the four sides and the lower portion of the body 110 are blocked by the bottom portion of the body so that the grid-shaped rib 130 can be secured to the outer half portion 120, respectively.

Accordingly, the deck of the present invention is referred to as a grid-type rib deck 100 in the sense that the four outer sides 150 and the grid-like ribs 130 are integrally formed.

That is, according to the bottom perspective view of the grid-shaped rib deck 100, a plurality of grid-shaped ribs 130 are formed in the shape of a cross, for example, on the inner side of the four outer sides of the wedge portion to form the grid-shaped ribs 130 and the four- It is understood that the inner space S in the form of a broken groove is partitioned on the bottom surface of the trunk portion 110. As shown in FIG.

As a result, it can be seen that the inner space S is formed in the lower part of the body 110 by the grid-shaped ribs 130 formed by engaging with the outer wedge parts 120 so as to intersect with each other in the long side direction and the short side direction .

Thus, while securing the inner space S, the weight of the lattice type rib deck can be reduced, and the load acting on the lattice type rib deck can be dispersed to the outer lattice portions of the four sides through the body portion and the lattice type ribs. Accordingly, it is possible to secure a more effective load-supporting performance and to suppress the generation of tensile cracks without increasing the thickness of the body portion.

Further, as shown in FIG. 2B, the inner reinforcing bars 140 are embedded in the inside of the body 110 by concrete. The inner reinforcing bars 140 are preformed in the mold and are embedded in the body 110 by pouring concrete.

Furthermore, a steel wire and / or an inner reinforcing bar may be additionally reinforced and reinforced inside the grid-shaped rib 130 and the outer sheath portion 120.

The inner reinforcing bars 140 serve to resist the weight of the rib-shaped rib deck 100 when lifted, and may also serve as a lower reinforcing steel of the slab (in the case of a half deck).

3B, the slab reinforcement (not shown), the upper slab reinforcement 510, or the upper slab reinforcement 510 may be installed to complete the slab reinforcement.

It can also be seen that the shear connector 150 coupled to the inner reinforcement 140 is formed to extend from the body 110 in the direction of the long side. At this time, it can be seen that the shear connector 150 is formed as a lattice reinforcement in the trunk portion.

[Grid Arch Rib Deck (100a)]

2C is a bottom perspective view and a cross-sectional view of the latticed arch rib deck 100a according to the present invention.

The lattice type arch rib deck 100a of the present invention includes a body 110, a four-side outer half portion 120, a latticed arch rib 131, an inner reinforcing bar 140, It is made of reinforced concrete using a mold.

Referring to FIG. 2C, the body 110 is also formed in a rectangular shape and is formed so that the long-side extension length in the longitudinal direction (the long-side direction) is larger than the short-side extension length in the short-side direction have.

The four sides of the long side and the short side of the body 110 are formed with four side outer half portions 120 integrally formed with the body portion. In other words, it can be seen that the four sides (outer peripheral end surface of the body portion) in the long side direction and the short side direction of the trunk portion are inclined downwardly by the outer tier portion 120.

2C, the outer hanging part 120 is formed as an outer lower downward inclined part 121 and an inner downward inclined part 122 and is integrally formed with the body 110, , And is mounted so as to be supported and supported on the outer half portion in the direction of the adjacent other long side.

At this time, the lower half of the outer half portion 120 of the four sides and the bottom portion of the body 110 are blocked out so that the lattice-shaped arch rib 131 is formed in the outer half portion (Not shown).

Accordingly, the deck of the present invention is referred to as a lattice type arch rib deck 100a in the sense that the four outer sides 150 and the lattice type arch ribs 131 are integrally formed.

In other words, according to a bottom perspective view of the lattice arch rib deck 100a, a plurality of latticed arch ribs 131 are formed in a cross shape on the inner side surfaces of the four outer sides of the outer lattice portion to form the lattice- It can be seen that the inner space S in the form of a broken groove is partitioned on the bottom surface of the body 110 by the body 120.

As a result, it can be seen that the inner space S is also formed in the lower part of the body 110 by the grid-shaped arch ribs 131 formed by engaging with the outer wedge part 120 so as to intersect with each other in the long- .

Thus, while securing the inner space (S), the weight of the lattice arch rib deck can be reduced, and the load acting on the lattice arch rib deck can be dispersed in the outer lattice sections of the four sides through the body and the lattice arch ribs . Accordingly, it is possible to secure a more effective load-supporting performance and to suppress the occurrence of tensile cracks without increasing the thickness of the body portion.

Further, the inner reinforcing bars 140 are embedded in the inside of the body 110 by the concrete. The inner reinforcing bars 140 are preformed in the mold and are embedded in the body 110 by pouring concrete.

Furthermore, a steel wire and / or an inner reinforcing bar may be additionally reinforced and reinforced inside the grid-shaped rib 130 and the outer sheath portion 120.

The inner reinforcing bars 140 serve to resist the weight of the rib-shaped rib deck 100 when lifted, and may also serve as a lower reinforcing steel of the slab (in the case of a half deck).

Accordingly, the slab according to the present invention can be constructed so that only the slab bottom reinforcing steel (not shown), the slab upper reinforcing steel 510, or the slab upper reinforcing steel 510 are laid out to complete the slab reinforcement as shown in FIG. 3C.

It can also be seen that the shear connector 150 coupled to the inner reinforcement 140 is formed to extend from the body 110 in the direction of the long side. At this time, it can be seen that the shear connector 150 is formed as a lattice reinforcement in the trunk portion.

[Connection structure of lattice type rib deck 100 and lattice type arch rib deck 100a]

3A and 3B are a perspective view and a connection sectional view of a lattice type rib deck 100 according to the present invention. (The lattice type arch rib deck 100a has the same connection structure,

First, as shown in FIG. 3A, it can be seen that the girder 400 is spaced apart from each other in the longitudinal direction in the bridge substructure 300 such as alternating bridge piers.

The slab 500 is installed on the upper surface of the girder 400. Since the slab 500 is a flat plate structure, it needs to be constructed to have a certain thickness by using a form. When a form is used, workability and workability are deteriorated, Is placed between the upper surface of the girder 400 and the slab concrete C is laid on the upper surface of the bridge deck to construct the slab 500.

However, as shown in FIG. 3A, if a steel box girder capable of constructing a long span bridge is used as the girder 400, the number of installation of the steel box girder itself can be reduced (minority casting) .

Therefore, the length of extension of the bridge deck in the long-side direction must be increased. In this case, tension cracks may be generated in the lower part of the body of the bridge deck. To compensate for this, 100, or a grid-like arch rib deck).

At this time, since the latticed rib deck 100 acts as a part of the slab 500, the working load must be transmitted to the girder 400. This load transfer must be dispersed as much as possible in order to achieve quality control and maintenance of the lattice rib deck 100.

To this end, as shown in FIG. 3A, the outer wedge portions 120 of the four sides of the latticed rib deck 100 are formed on the upper surface of the girder 400 adjacent to the lateral direction

The outer half portions 120a and 120b in the short side direction are separated from each other. Thereby enabling basic support by the outer wedge part 120, and further,

The outer half portion 120c in the one long side direction is divided into two parts to be referred to as a portion of the girder 400. The girder 400 is supported on the upper side of the horizontal beam 410 installed laterally.

Since the girders 400 are spaced apart in the lateral direction during the construction of the bridges, it is necessary to constrain them in the lateral direction. In the case of a steel box girder, the crossbeam 410 is usually installed using an I-beam steel frame, and the outer side half portion 120c in the one long side is supported on the upper flange of the crossbeam 410 .

The other outer long side outer half portion 120d (which is also divided to refer to the region) is supported so as to be mutually supported on one side long side outer half portion 120c of the adjacent grid type rib deck 100 of the present invention .

In other words, the outer grid-shaped ribs 120c of the adjacent grid-shaped rib decks 100 can be supported by the stepped portions.

Particularly, in the present invention, the rib-type rib decks 100 are provided adjacent to each other in the horizontal direction as shown in FIG. 3B, so that they can be connected to each other by a simple lifting operation. Since the loss of the effective cross section due to the increase in the thickness from the slab surface to the slab surface is reduced so much, it is very effective in suppressing the reflection cracks.

Thus, the grid-shaped rib deck 100 according to the present invention can be stably mounted on the girder 400 and the beam 410 by the four outer side portions 120a, 120b, 120c and 120d, The cross-sectional loss of the slab is minimized at the connecting portions of the spiral portions, so that reflection cracks and the like are prevented from occurring.

Referring to FIG. 3B, it can be seen that the shear connectors 150 located at the connecting portions of the outer sheath portions in the long-side direction are adjacent to each other.

That is, when the lattice reinforcement is used as the shear connector 150, it can be seen that the effective thickness of the slab decreases due to the outer downward slope portion 121 at the connecting portion of the outer sheath portions in the long side direction.

Accordingly, in order to restrain the upper portion of the connection portion, the present invention provides a connection reinforcing bar 160 which is disposed at the end of the shear connection member and is adjacent to the adjacent shear connection members 150, .

[Method of constructing lattice type rib deck 100 and lattice type arch rib deck 100]

4A, 4B, and 4C show the grid-type rib deck construction method of the present invention in order (although not shown, the same applies to the grid-shaped arch rib deck 100a)

First, as shown in FIG. 4A, the bridge substructure 300 is alternately installed, and the girder 400 is installed on the bridge substructure 300.

It can be seen that a steel box girder in the form of a steel box body is mounted as the girder, and the number of the girders 400 to be installed in the lateral direction can be changed. However, in FIG. 4A, three girders are installed.

Between the upper flanges of these girders 400, the grid-shaped rib deck 100 of the present invention is also lifted in the lateral direction.

At this time, it is understood that a crossbeam 410, which is an I-beam steel frame, is installed to extend in the transverse direction between the girders 400 installed in the lateral direction, and a plurality of beams 410 are installed.

Since the crossbeam 410 is necessarily installed in the girder bridges, the present invention uses the crossbeam 410 in the ribbed rib deck 100.

As shown in FIG. 3A, the outer wedge portions 120 of the four sides of the ribbed deck 100 are installed such that the outer wedge portions 120a and 120b are supported on the upper surface of the girder 400, So that it is possible to provide basic support by the outer swinging part 120.

It can be seen that the grid-shaped rib deck 100 is installed such that the one side long side outer side hook portion 120c is supported on the upper flange of the side beam 410 at a position where the side beam 410 is installed.

In addition, the outer side long side outer half portion 120d is formed so as to be supported on the outer side portion of the adjacent grid type rib deck 100 of the present invention, and the outer side of the adjacent grid type rib deck 100, It can be seen that the support portion 120c is supported by the stepped portions.

When the installation of the grid-type rib deck 100 to be installed is completed, the grid-shaped rib deck 100 according to the present invention is formed by four outer side portions 120a, 120b, 120c and 120d, It is possible to provide a more stable mounting on the outer side 410 and to be supported on the connection part of the outer side of the other long side direction.

Next, as shown in FIG. 4B, a connecting reinforcing bar 160 is installed between adjacent shear connecting members 150 located at the connecting portions of the outer sheathing portions in the long-side direction, so that the reflective cracks 160 can be restrained .

Next, as shown in FIG. 4C, a slab bottom reinforcing bar (not shown) is laid out by using a spacing material or the like, the slab reinforcing bar 510 is laid and the slab reinforcing bar 510 is embedded . The slab concrete is poured and cured at a constant thickness to complete the slab 500.

In this case, since the inner reinforcing bars 140 of the lattice-shaped rib deck 100 according to the present invention can also serve as the lower reinforcing bars of the slabs, the lower reinforcing bars of the slabs are not separately installed, The slab lower reinforcing bars (not shown) and the upper slab reinforcing bars 510 may be placed on the lattice rib deck 100 if they do not serve as the lower reinforcing bars.

The shear connection member 150 serves to synthesize the slab concrete C and the grid type rib deck 100 integrally with each other and the connection reinforcing bar 160 is connected to the long- So that the load transmitted to the slab is reduced by the four-side support of the grid-type rib deck 100, So that they are transferred to the girder 400. [

Further, since the grid-shaped arch rib deck 100a differs from the grid-shaped rib deck 100 in the shape of the grid ribs, the grid-shaped arch rib deck 100a is the same as the grid-type rib deck 100 in the construction method thereof.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Grating rib deck
100a: Grating Arch Rib Deck
110: body portion 120: outer half portion
120a, 120b: an outer half portion in the short side direction
120c: one side long side outer half portion
120d: Outside half portion in the other long side direction
121: outer downward inclined portion 122: inner downward inclined portion
130: Grating rib 131: Grating arch rib
140: inner reinforcement 150: shear connector
160: connecting rebar 300: bridge substructure
400: girder 410: beam
500: Slab 510: Upper slab reinforcement

Claims (10)

An outer half portion 120 integrally formed with both ends of the body 110 in both the longitudinal and lateral directions; And
Shaped ribs 130 integrally formed so as to extend orthogonally to each other in the long-side direction and the short-side direction between the inside of the outer half-portion 120 so as to secure a partitioned inner space S having a groove- ), ≪ / RTI >
The outer side half portion 120a and the outer side half portion 120b constituting the outer side half portion 120 are respectively supported on the upper surface of the girder and the one side long side outer half portion 120c is disposed between the inside of the girder 400 in the lateral direction And the other outer long side outer half portion 120d is supported by the outer sheath portion of the adjoining grid type rib deck 100 to be supported by the step. The method according to claim 1,
An inner reinforcing bar 140 is embedded in the body 110 to form a front end connecting member 150 protruding from an upper surface of the body 110. The method according to claim 1,
At this time, the outer half-portion 120 is formed by the outer downward slope portion 121 and the inner downward slope portion 122 and is integrally formed with the body 110, and the outer long-side outer half portion 120d is adjacent Shaped rib deck to be supported by the one side long side outer half portion 120c of the rib type rib deck. The method according to claim 1,
And a connecting reinforcing steel bar (160) for crossing the adjacent shear connecting members (150) to each other for restricting the connecting portions of the outer sheathing portions in both longitudinal sides. An outer half portion 120 integrally formed with both ends of the body 110 in both the longitudinal and lateral directions; And
Shaped arch ribs (120) formed so as to extend orthogonally to each other in the long-side direction and the short-side direction between the inside of the outer half-portion 120 so as to secure a partitioned inner space (S) 131)
The outer side half portion 120a and the outer side half portion 120b constituting the outer side half portion 120 are respectively supported on the upper surface of the girder and the one side long side outer half portion 120c is disposed between the inside of the girder 400 in the lateral direction And the other outer long side outer half portion 120d is supported by the outer sheath portion of the adjoining grid type rib deck 100 in a stepped manner. 6. The method of claim 5,
An inner reinforcing bar 140 is embedded in the body 110 and a front end coupling 150 protruding from an upper surface of the body 110 is formed.
At this time, the outer half-portion 120 is formed by the outer downward slope portion 121 and the inner downward slope portion 122 and is integrally formed with the body 110, and the outer long-side outer half portion 120d is adjacent Shaped arch rib deck, and a connecting reinforcing steel bar 160 which crosses adjacent shear connecting members 150 in order to restrain the connecting portions of the outer long-side outer sheathing portions More grid-like arch rib deck to install. (a) The girder ribs 100 according to the first aspect of the present invention are installed by using a girder and a beam, and the both short side outer side helices 120a and 120b constituting the outer side helices 120 are respectively supported on the upper surface of the girders. And the outer side half portion 120c in the one long side direction is supported on the upper surface of the cross beam 410 installed in the lateral direction between the inner side of the girder 400 and the outer side long side portion 120d in the other long side direction is supported by the adjacent grid Type rib deck (100); And
(b) placing the slab concrete on top of the lattice-shaped rib tee 100; 8. The method of claim 7,
After the step (b), (c) installing a connection reinforcing bar 160 crossing the upper portion of the connecting portion between adjacent shear connecting members 150 located at the connecting portions of the outer sheathing portions in the both long- Wherein the ribbed deck is formed by a plurality of ribs. (a) The grid-like arch rib tec 100a according to claim 5 is installed using a girder and a beam, both longitudinal side outer wedge parts 120a and 120b constituting the outer wedge part 120 are supported on the upper surface of the girder, And the one side long side outer hook portion 120c is supported on the upper side of the cross beam 410 installed between the inside of the girder 400 and the other side long side outer helical portion 120d is installed adjacent So as to have a step-like support on the outer spiral portion of the latticed arch rib deck 100a; And
(b) placing the slab concrete on top of the latticed arch rib tee 100a. 10. The method of claim 9,
After step (b), the step (c) of installing the connecting rebar 160 crossing the upper part of the connecting part between adjacent shear connecting members 150 located at the connecting parts of the outer sheathing parts in the opposite lateral long- Lt; RTI ID = 0.0 > rib-deck < / RTI >

Images