KR101530351B1 - Composite slab with steel fiber reinforced concrete-deckplate and construction method thereof - Google Patents

Abstract

The present invention relates to a steel fiber reinforced concrete and deck plate composite slab which eliminates an upper re-bar by pouring steel fiber reinforced concrete to the top of a deck plate to apply tension and control temperature and shrinkage cracks and a construction method thereof. According to the present invention, the steel fiber reinforced concrete and deck plate composite slab is made of steel fiber reinforced concrete as a mixture of concrete and a steel fiber, wherein a deck plate comprises: a flat part as a flat plate; a first joint part comprising a first vertical part protruding from the top of the flat part, a first horizontal part vertically bent outward from the first vertical part, and a first hooking part vertically bent downward from the outer end of the first horizontal part; a second joint part comprising a second vertical part protruding from the top of the flat part, a second horizontal part vertically bent outward from the second vertical part, and a second hooking part vertically bent downward from the outer end of the second horizontal part; and first and second reinforcement joint parts disposed above the flat part at a predetermined distance from each inner side of the first and second joint parts.

Description

Composite slab with steel fiber reinforced concrete-deckplate and construction method < RTI ID = 0.0 >

The present invention can eliminate the upper reinforcing steel by controlling the temperature and shrinkage crack by supplementing the tensile force of concrete by placing steel fiber concrete on the upper part of the deck plate and by using a standardized deck plate, Steel fiber concrete-deck plate composite slab and its construction method.

The deck plate constitutes the floor slab of the building and is integrated with the upper concrete to form a composite slab structure.

The deck plate is widely used because it is lightweight, easy to handle, easy to install, and does not require a supporting support for long span slab construction, which can shorten the construction time and reduce construction cost.

However, when the deck plate is used, when the width of the slab is not a multiple of the width of the deck plate, there is a disadvantage that a machining process such as cutting the outermost deck plate is required.

That is, if the width of the slab is a multiple of the width of the deck plate, the same deck plate can be arranged and arranged. However, if the width of the slab is not a multiple of the width of the deck plate, a separate deck plate having a narrow width with the outermost deck plate is required.

Therefore, it is necessary to cut the deck plate one by one in accordance with the width of the slab of various sizes, which causes the air to increase. If the cut dimensions are not correct, the quality may be deteriorated.

On the other hand, in order to reinforce concrete with a weak tensile strength, steel fiber concrete made by adding and dispersing a steel fiber into a mixture of cement and aggregate has been used (Patent Application No. 10-2003-0084817, etc.).

This steel fiber concrete is used to reinforce the concrete by being dispersed evenly in the concrete. However, in the process of mixing the steel fiber or compaction of the concrete, the steel fiber may not be evenly distributed and may be arranged in a certain direction.

This steel fiber arrangement makes it difficult to expect the strength enhancement effect of concrete in a certain direction.

According to an aspect of the present invention, an outboard deck plate is disposed on a deck plate so as to partially overlap an adjacent deck plate when the width of the slab is not a multiple of the deck plate width. Steel fiber concrete-deck plate composite slab and a construction method thereof.

It is another object of the present invention to provide a seamless steel fiber concrete-deck plate composite slab excellent in the effect of reinforcing concrete strength and preventing cracks by uniformly dispersing the direction of the steel fiber mixed in the concrete, and a method of construction thereof.

According to a preferred embodiment of the present invention, there is provided a steel fiber concrete deck plate composite slab comprising a deck plate and a steel fiber concrete poured over the deck plate, the steel fiber being mixed with concrete, The deck plate is a flat plate; A first vertical part protruding upward from a flat part provided to be protruded from both sides of the flat part, a first horizontal part bent vertically outward from the first vertical part, and a second vertical part bent vertically downward from the outer end of the first horizontal part, A second vertical portion protruding to the upper portion of the flat portion, a second horizontal portion bent inwardly inwardly from the second vertical portion, and a second vertical portion bent downward from the inner end of the second horizontal portion A second engaging portion formed by a vertically bent second engaging portion; And a first reinforcing portion and a second reinforcing portion provided on an upper portion of the flat portion, the first reinforcing portion and the second reinforcing portion being spaced apart from each other by a predetermined distance inwardly from the first engaging portion and the second engaging portion. Wherein a distance between the first engaging portion and the first reinforcing and engaging portion is equal to a distance between the second engaging portion and the second reinforcing and engaging portion so that the first engaging portion and the first reinforcing and engaging portion are adjacent to each other, And the outer lengths of the second vertical portion and the second horizontal portion of the second engaging portion are set so that the first vertical portion of the first engaging portion and the second horizontal portion of the first horizontal portion Wherein the first reinforcing coupling portion comprises a pair of third vertical portions protruding upward so as to be spaced apart from each other at the flat portion and a third horizontal portion interconnecting the upper ends of the third vertical portion, The inner lengths of the third vertical portion and the third horizontal portion are the same as the outer lengths of the second vertical portion and the second horizontal portion of the second coupling portion and the inner lengths of the first vertical portion and the first horizontal portion of the first coupling portion are The same as the outer length of the height and width of the second reinforcing coupling portion Wherein the steel slab is made of a non-slip steel fiber concrete-deck plate composite slab.

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According to another preferred embodiment of the present invention, the second reinforced coupling portion is T-shaped, and the present invention provides an asymmetric steel fiber concrete deck plate composite slab.

According to another preferred embodiment of the present invention, a support portion is protruded inwardly from one side of a third vertical portion of the third vertical portion on the third vertical portion, the height of the upper end of the support portion is lower than the height of the lower end of the second engagement portion And a reinforced concrete-deck plate composite slab.

According to another preferred embodiment of the present invention, the deck plate is formed by continuously bending a single plate, and provides a composite steel slab of a non-steel fiber concrete deck plate.

According to another preferred embodiment of the present invention, a plurality of rib-reinforced portions are formed on the flat portion so as to protrude from the flat portion.

According to another preferred embodiment of the present invention, the distance between the upper end of the deck plate and the upper surface of the slab is 90 mm or more and 100 mm or less.

According to another preferred embodiment of the present invention, the steel fiber concrete comprises 30 to 120 kg of steel fiber per cubic meter of concrete.

According to another preferred embodiment of the present invention, the steel fiber is composed of a straight body and a fusing part bent at both ends of the main body, respectively, to provide a composite steel slab of a non-steel fiber concrete deck plate.

According to another aspect of the present invention, there is provided a composite steel slab for an unguarded steel fiber concrete deck plate, wherein an end portion of the fusing unit is further provided with an auxiliary fixing unit bent in a direction perpendicular to the surface of the main body and the fixing unit.

According to still another aspect of the present invention, there is provided a method of constructing a seamless steel fiber concrete deck plate composite slab, comprising the steps of: (a) arranging a plurality of deck plates other than the outermost deck plate in contact with each other; (b) disposing the outermost deck plate so that it partially overlaps with an adjacent first installed deck plate; (c) placing a steel fiber concrete mixed with a steel fiber in an upper portion of the deck plate; And (d) curing the concrete; Wherein the deck plate is a flat plate; A first vertical part protruding upward from a flat part provided to be protruded from both sides of the flat part, a first horizontal part bent vertically outward from the first vertical part, and a second vertical part bent vertically downward from the outer end of the first horizontal part, A second vertical portion protruding to the upper portion of the flat portion, a second horizontal portion bent inwardly inwardly from the second vertical portion, and a second vertical portion bent downward from the inner end of the second horizontal portion A second engaging portion formed by a vertically bent second engaging portion; And a first reinforcing coupling portion and a second reinforcing coupling portion provided on an upper portion of the flat portion, the first reinforcing coupling portion and the second reinforcing coupling portion being spaced apart from each other by a predetermined distance inward from the first coupling portion and the second coupling portion; Wherein the first reinforcing coupling portion comprises a pair of third vertical portions protruding upward from the flat portion and a third horizontal portion connecting the upper ends of the third vertical portions, The inner lengths of the horizontal portions are respectively equal to the outer lengths of the second vertical portions and the second horizontal portions of the second coupling portions, and the inner lengths of the first vertical portions and the first horizontal portions of the first coupling portions are respectively equal to the height of the second reinforcing coupling portions, Wherein a distance between the first engaging portion and the first reinforcing engaging portion is the same as a distance between the second engaging portion and the second reinforcing engaging portion, and in the step (b) Deck plate composite slab according to any one of the preceding claims, wherein the first and second reinforcing coupling portions of the deck plate are coupled to the upper portions of the second reinforcing coupling portion and the second coupling portion of the adjacent first installed deck plate, respectively.

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According to another preferred embodiment of the present invention, a support portion is protruded inwardly from one side of a third vertical portion of the third vertical portion on the third vertical portion, the height of the upper end of the support portion is lower than the height of the lower end of the second engagement portion The present invention also provides a method of constructing an unglazed steel fiber concrete deck plate composite slab.

The present invention has the following effects.

First, the first and second engaging portions and the first and second reinforcing engaging portions are protruded on the flat portion of the deck plate and the distance and the size between the first and second engaging portions are adjusted so that even when the slab width is not a multiple of the deck plate width, A part of the deck plate can be overlapped with the adjacent deck plate. Therefore, it is possible to construct the slab with only the standardized deck plate without a separate narrow deck plate.

Secondly, by constructing an anchor portion bent at both ends of a steel fiber and constituting an auxiliary fixing portion bent in the out-of-plane direction at an end portion of the anchor portion, the steel fibers mixed in the concrete are dispersed in an even direction, thereby enhancing concrete strength and preventing cracks.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view of an inventive seamless steel fiber concrete-deck plate composite slab. FIG.
2 is a perspective view of the inventive seamless steel fiber concrete-deck plate composite slab.
3 is a perspective view of a deck plate;
4 is a side view showing an embodiment of a coupling relationship of adjacent deck plates.
Fig. 5 is a side view showing another embodiment of the coupling relationship of adjacent deck plates. Fig.
6 is a perspective view showing another embodiment of the coupling relationship of adjacent deck plates;
7 is a perspective view showing an embodiment of a steel fiber.
8 is a perspective view showing another embodiment of the steel fiber.

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

FIG. 1 is a sectional view of the inventive seamless steel fiber concrete-deck plate composite slab, FIG. 2 is a perspective view of the inventive seamless steel fiber concrete-deck plate composite slab, and FIG. 3 is a perspective view of the deck plate.

1 and 2, the non-woven steel fiber concrete-deck plate composite slab of the present invention is laid on the deck plate 10 and the deck plate 10, and the steel fiber 22 is embedded in the concrete 21, And a steel fiber concrete (20) mixed with the steel fiber (20).

The deck plate 10 can be formed by continuously bending a single plate such as a steel plate, and constitutes a concrete and a composite slab to supplement the tensile force of the concrete.

The steel fiber concrete 20 is mixed with the steel fiber 22 in the concrete 21 so that the steel fiber 22 is uniformly dispersed in the concrete 21 to reinforce the tensile force of the concrete 21 and suppress cracking.

Since the steel fiber 22 on the deck plate 10 reinforces the tensile force of the slab, it is not necessary to separately reinforce the upper portion of the deck plate 10, and the rustproof treatment is applied to the lower surface of the deck plate 10 as the case may be.

As shown in FIGS. 1 and 3, the deck plate 10 includes a flat plate 11; A first engaging part 12 and a second engaging part 13 respectively provided to project upward from both sides of the flat part 11; And a first reinforcing and attaching part 14 and a second reinforcing and engaging part 15 provided on the flat part 11 so as to be spaced apart from each other in the first and second engaging parts 12 and 13, ); And the distance between the first engaging portion 12 and the first reinforcing and engaging portion 14 is equal to the distance between the second engaging portion 13 and the second reinforcing and engaging portion 15, The coupling portion 12 and the first reinforcing coupling portion 14 are respectively coupled to the second reinforcing coupling portion 15 and the second coupling portion 13 of the adjacent deck plate 10, do.

4, the first engaging portion 12 and the second engaging portion 13 of the adjacent deck plate 10 can be engaged with each other. When the width of the deck plate 10 to be installed is narrow The first engaging portion 12 of the deck plate 10 " to be installed later on the second reinforcing engaging portion 15 and the second engaging portion 13 of the pre-installed deck plate 10 ' And the first reinforcing engagement portion 14 can be engaged with each other.

Therefore, it is possible to control the width of the deck plate to be finally installed by overlapping the adjacent deck plates. That is, when the width of the slab is narrower than the width of the deck plate, the outermost deck plate can be partially overlapped with the adjacent deck plate, and the slab can be constructed with only the standard deck plate without a narrow deck plate.

Particularly, even when the width of the deck plate needs to be changed, such as at the pillar portion or around the opening, the adjacent deck plates can be overlapped.

As shown in FIG. 3, a plurality of rib reinforcement portions 16 may be formed on the flat portion 11 in a protruding manner.

The rib reinforcing portion 16 reinforces the rigidity of the deck plate 10 and widens the bonding area with the concrete so as to integrate with the slab concrete.

The distance between the upper end of the deck plate 10 and the upper surface of the slab may be 90 mm or more and 100 mm or less.

If the distance between the upper end of the deck plate 10 and the upper surface of the slab is 90 mm or less, the total amount of steel fibers is insufficient, If it exceeds 100mm, the weight of the slab is excessive and a separate reinforcement is necessary.

The steel fiber concrete (20) is characterized in that 30 to 120 kg of the steel fiber (22) is mixed per 1 m 3 of the concrete (21).

If the steel fiber is less than 30 kg, the effect of mixing the steel fiber is difficult to expect. If the steel fiber is more than 120 kg, the fluidity of the concrete is deteriorated.

Fig. 4 is a side view showing an embodiment of the engagement relationship of adjacent deck plates. Fig.

4, the first engaging portion 12 includes a first vertical portion 121 protruded above the flat portion 11, a first vertical portion 121 protruding outward from the first vertical portion 121, And a first engaging portion 123 bent downward from an outer end of the first horizontal portion 122. The second engaging portion 13 is formed at an upper portion of the flat portion 11 A second horizontal portion 132 that is vertically bent inward from the second vertical portion 131 and a second horizontal portion 132 that is vertically bent downward from the inner end of the second horizontal portion 132 And an outer length of the second vertical part 131 and the second horizontal part 132 of the second engaging part 13 may be the same as the length of the first vertical part of the first engaging part 12 121 and the first horizontal portion 122, respectively.

The first engaging portion 12 of the deck plate 10 to be installed later can be engaged with the upper portion of the second engaging portion 13 of the pre-installed deck plate 10.

That is, the first engaging portion 12 of the deck plate 10 provided adjacent to the outside of the second engaging portion 13 is abutted and engaged.

At this time, if the lengths of the first horizontal part 122 and the second horizontal part 132 are increased, the amount of concrete on the upper part of the deck plate 10 can be adjusted, so that it can be configured as a lightweight member.

Fig. 5 is a side view showing another embodiment of the engagement relationship of the adjacent deck plates, and Fig. 6 is a perspective view showing another embodiment of the engagement relationship of the adjacent deck plates.

As shown in FIGS. 5 and 6, in the present invention, the first reinforcing and attaching part 14 includes a pair of third vertical parts 141a and 141b protruding upward from the flat part 11, And a third horizontal portion 142 connecting the upper ends of the first vertical portions 141a and 141b so that the inner lengths of the third vertical portions 141a and 141b and the third horizontal portion 142 are 2 of the first engaging portion 12 and the outer length of the second vertical portion 131 and the second horizontal portion 132 of the first engaging portion 13 and the outer length of the second vertical portion 131 and the second horizontal portion 132 of the first engaging portion 13, The inner lengths of the first reinforcing portions 122 are equal to the outer lengths of the height and width of the second reinforcing portions 15, respectively.

That is, the size of the second reinforcing coupling portion 15 and the second coupling portion 13 of the pre-installed deck plate 10 'may be adjusted to be larger than the size of the first coupling portion 12 of the deck plate 10 " The second reinforcing and engaging portion 15 and the second engaging portion 13 of the pre-installed deck plate 10 'are formed to be smaller than the size of the reinforcing and engaging portions 14, To be inserted into the first engaging portion 12 and the first reinforcing engaging portion 14 of the deck plate 10 "

4, when the lengths of the first horizontal part 122 and the second horizontal part 132 and the widths of the third horizontal part 142 and the second reinforcing part 15 are increased, The amount of concrete can be adjusted, so that a lightweight member can be constructed.

The width of the second reinforcing coupling portion 15 and the width of the second horizontal portion 132 of the second engaging portion 13 are set to be equal to the width of the first horizontal portion 122 and the width of the third horizontal portion 142, The deck plate 10 "to be installed later can be moved in the horizontal direction, so that it can be applied to the slab widths of various lengths.

At this time, the second reinforcing coupling portion 15 may be formed in a T shape so as to be integrated with the concrete 21 buried in the slab.

A support portion 143 protrudes inward from one side of the third vertical portion 141a of the first vertical portion 141a and the third vertical portion 141b of the first vertical portion 141b, The lower end of the second engaging part 133 is lower than the height of the lower end of the second engaging part 133.

As a result, the first reinforcing joint portions 14 of the deck plate 10 "to be installed later are firmly fixed to the second engaging portions 13 of the pre-installed deck plate 10 'and are not separated from each other.

In the embodiment of FIG. 5, the support portion 143 has a semicircular cross-section and can be easily inserted into the upper portion of the second engaging portion 13.

Fig. 7 is a perspective view showing an embodiment of the steel fiber, and Fig. 8 is a perspective view showing another embodiment of the steel fiber.

As shown in FIG. 7, the steel fiber 22 may include a straight body 221 and a fusing unit 222 bent at both ends of the body 221.

The fixing unit 222 is engaged with the concrete 21 to integrate the concrete 21 with the steel fiber 22 and the steel fiber 22 is mixed in two directions.

8, an auxiliary fixing unit 223 may be further provided at an end of the fixing unit 222. The auxiliary fixing unit 223 may be bent in a direction perpendicular to the surface of the main body 221 and the fixing unit 222. As shown in FIG.

The structure of the auxiliary fusing unit 223 that is vertically bent out of the plane not only increases integration with the concrete 21 but also allows the adjacent steel fibers 22 to be fixed to the auxiliary fusing unit 223, ), And the tensile reinforcement effect can be obtained in three directions.

Next, a method of constructing a non-woven steel fiber concrete-deck plate composite slab will be described.

(A) a plurality of deck plates other than the outermost deck plate 10 "are disposed on the upper end of the beam 1 so as to be in contact with each other, as shown in Fig. 6, (b) The outermost deck plate 10 "is disposed so as to partially overlap with the adjacent first deck plate 10 '.

A shear connection material may be welded to the upper portion of the beam (1) or deck plate (10) to increase the composite force with concrete.

At this time, the deck plate 10 includes a flat plate 11; A first engaging part 12 and a second engaging part 13 respectively provided to project upward from both sides of the flat part 11; And a first reinforcing and attaching part 14 and a second reinforcing and engaging part 15 provided on the flat part 11 so as to be spaced apart from each other in the first and second engaging parts 12, ; Wherein a distance between the first engaging portion 12 and the first reinforcing and engaging portion 14 is equal to a distance between the second engaging portion 13 and the second reinforcing and engaging portion 15, the first reinforcing joint portion 12 of the outermost deck plate 10 "and the first reinforcing and engaging portion 14 of the outermost deck plate 10 ' 2 coupling portions 13, respectively.

Therefore, the adjacent deck plates 10 'and 10 "can be overlapped to adjust the width of the deck plate 10"

(C) placing a steel fiber concrete 20 mixed with a steel fiber 22 on the concrete 21 on the deck plate 10, and (d) curing the concrete 21.

The first engaging portion 12 includes a first vertical portion 121 protruded above the flat portion 11, a first horizontal portion 122 vertically bent outward from the first vertical portion 121, And a first engaging part 123 bent downward at an outer end of the first horizontal part 122. The second engaging part 13 includes a second vertical part protruding above the flat part 11 A second horizontal portion 132 that is vertically bent inward from the second vertical portion 131 and a second hook portion 133 that is vertically bent downward from an inner end portion of the second horizontal portion 132, The first reinforcing and attaching part 14 includes a pair of third vertical parts 141a and 141b projecting upward from the flat part 11 and connecting the upper ends of the third vertical parts 141a and 141b And the inner lengths of the third vertical parts 141a and 141b and the third horizontal part 142 are respectively set to the second vertical part 131 of the second engaging part 13, And an outer length of the second horizontal portion 132, and the first vertical portion 12 1 and the first horizontal portion 122 may be the same as the outer lengths of the height and width of the second reinforcing coupling portion 15, respectively.

5 (b), the second reinforcing coupling portion 15 and the second coupling portion 13 of the pre-installed deck plate 10 'are fitted to the first coupling portion 13''of the deck plate 10' The first reinforcing coupling portion 14 and the second reinforcing coupling portion 14 can be engaged with each other.

A supporting portion 143 protrudes inwardly from one side of the third vertical portion 141a of the third vertical portion 141a and 141b on the side of the first engaging portion 12, 2 engaging portion 133. In this case,

Thus, the first reinforcing joint portion 14 of the deck plate 10 "to be installed later can be firmly fixed to the second engaging portion 13 of the pre-installed deck plate 10 'and can not be separated from each other.

1: beam 10, 10 ', 10 ": deck plate
11: flat part 12: first coupling part
121: first vertical part 122: first horizontal part
123: first engaging portion 13: second engaging portion
131: second vertical part 132: second horizontal part
133: second engaging part 14: first reinforcing part
141a, 141b: third vertical part 142: third horizontal part
143: Support part 15: Second reinforcing part
16: rib reinforcement part 20: steel fiber concrete
21: concrete 22: steel fiber
221: main body 222: fusing unit
223: auxiliary fixing unit

Claims (14)

Deck plate composite slab comprising a deck plate 10 and a steel fiber concrete 20 which is placed on the deck plate 10 and mixed with a steel fiber 22 in a concrete 21,
The deck plate 10 includes a flat portion 11, which is a flat plate;
A first vertical part 121 protruding upward from the flat part 11 provided to be protruded upward from both sides of the flat part 11, a first vertical part 121 vertically bent outward from the first vertical part 121, And a first engaging portion 12 formed of a first engaging portion 123 vertically bent downward from an outer end of the first horizontal portion 122 and a second engaging portion 123 formed of a second A second horizontal portion 132 that is vertically bent inward from the second vertical portion 131 and a second hook portion 133 that is vertically bent downward from an inner end portion of the second horizontal portion 132, A second engaging portion 13 composed of a first engaging portion 13a and a second engaging portion 13b. And
A first reinforcing and engaging part 14 and a second reinforcing and engaging part 15 provided on the flat part 11 so as to be spaced apart from each other by a predetermined distance inward from the first engaging part 12 and the second engaging part 13, ; ≪ / RTI >
The distance between the first engaging portion 12 and the first reinforcing and engaging portion 14 is the same as the distance between the second engaging portion 13 and the second reinforcing and engaging portion 15, And the first reinforcing coupling portion 14 are respectively coupled to the second reinforcing coupling portion 15 and the second coupling portion 13 of the adjacent first installed deck plate 10,
The outer lengths of the second vertical part 131 and the second horizontal part 132 of the second engaging part 13 are set such that the first vertical part 121 and the first horizontal part 122 of the first engaging part 12 Respectively,
The first reinforcing and attaching part 14 includes a pair of third vertical parts 141a and 141b protruding upward from the flat part 11 and upper ends of the third vertical parts 141a and 141b, And the inner lengths of the third vertical parts 141a and 141b and the third horizontal part 142 are respectively set to the second vertical parts of the second engaging part 13 131 and the outer length of the second horizontal portion 132,
The inner lengths of the first vertical portion 121 and the first horizontal portion 122 of the first coupling portion 12 are equal to the outer lengths of the height and width of the second reinforcing coupling portion 15, Non - slip steel fiber concrete - deck plate composite slab.
delete delete The method of claim 1,
Wherein the second reinforcing coupling portion (15) is a T-shaped reinforced concrete fiber-concrete deck plate composite slab.
The method of claim 1,
A supporting portion 143 protrudes inward from one side of the third vertical portion 141a of the first vertical portion 141a and the third vertical portion 141b of the third vertical portion 141b, Is located lower than the height of the lower end of the locking part (133).
The method according to any one of claims 1, 4, and 5,
The deck plate (10) is formed by continuously bending a single plate.
The method according to any one of claims 1, 4, and 5,
And a plurality of rib reinforcing portions (16) are formed on the flat portion (11) so as to protrude from the flat portion (11).
The method of claim 1,
Wherein the distance between the upper end of the deck plate (10) and the upper surface of the slab is 90 mm or more and 100 mm or less.
The method of claim 1,
Wherein the steel fiber concrete (20) is mixed with 30 to 120 kg of the steel fiber (22) per 1 m 3 of the concrete (21).
The method of claim 1,
Wherein the steel fiber (22) is composed of a straight body (221) and a fusing part (222) bent at both ends of the body (221).
11. The method of claim 10,
And an auxiliary fixing unit (223) bent in a direction perpendicular to the surface of the body (221) and the fixing unit (222) is formed at an end of the fixing unit (222) Slabs.
The present invention relates to a method of constructing a non-woven steel fiber concrete-deck plate composite slab,
(a) arranging a plurality of deck plates other than the outermost deck plate 10 "
(b) disposing the outermost deck plate 10 "so that it partially overlaps with the adjacent first installed deck plate 10 ';
(c) placing a steel fiber concrete (20) mixed with a steel fiber (22) on a concrete (21) on the deck plate (10); And
(d) curing the concrete (21); , ≪ / RTI &
The deck plate 10 includes a flat portion 11, which is a flat plate; A first vertical part 121 protruding upward from the flat part 11 provided to be protruded upward from both sides of the flat part 11, a first vertical part 121 vertically bent outward from the first vertical part 121, And a first engaging portion 12 formed of a first engaging portion 123 vertically bent downward from an outer end of the first horizontal portion 122 and a second engaging portion 123 formed of a second A second horizontal portion 132 that is vertically bent inward from the second vertical portion 131 and a second hook portion 133 that is vertically bent downward from an inner end portion of the second horizontal portion 132, A second engaging portion 13 composed of a first engaging portion 13a and a second engaging portion 13b. And a first reinforcing and attaching part 14 and a second reinforcing and engaging part 15 provided on the flat part 11 so as to be spaced apart from each other in the first and second engaging parts 12, ; ≪ / RTI >
The first reinforcing coupling portion 14 includes a pair of third vertical portions 141a and 141b protruding upward from the flat portion 11 and a third vertical portion 141a and 141b projecting upward from the flat portion 11, And the inner lengths of the third vertical portions 141a and 141b and the third horizontal portion 142 are respectively equal to the lengths of the second vertical portion 131 and the second vertical portion 131 of the second engaging portion 13, 2 horizontal portion 132,
The inner lengths of the first vertical portion 121 and the first horizontal portion 122 of the first coupling portion 12 are the same as the outer lengths of the height and width of the second reinforcing coupling portion 15,
The distance between the first engaging part 12 and the first reinforcing engaging part 14 is equal to the distance between the second engaging part 13 and the second reinforcing engaging part 15, The first reinforcing coupling portion 15 and the second coupling portion 12 of the previously installed deck plate 10 'adjacent to the first coupling portion 12 and the first reinforcing coupling portion 14 of the outermost deck plate 10 " 13. The composite slab according to claim 1,
delete The method of claim 12,
A supporting portion 143 protrudes inward from one side of the third vertical portion 141a of the first vertical portion 141a and the third vertical portion 141b of the third vertical portion 141b, Wherein the reinforcing member is located below the lower end of the locking part.

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