KR101701416B1 - Precast Concrete Deck for Long-Span Slab and the Slab using it - Google Patents

Abstract

The present invention relates to a precast concrete deck for a long-span slab, and a slab using the same. According to an embodiment of the present invention, a precast concrete deck for a long-span slab is characterized such that at least one first strand is fixated to a bottom of a rib to penetrate a bottom plate portion while at least one second strand shorter than the first strand is fixated to an upper portion of the first strand to penetrate the rib, and negative bending moment generating on both ends being able to be reduced; thereby preventing an occurrence of a crack by preventing the precast concrete deck from exceeding bending and cracking strength.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a precast concrete deck for a long-span slab and a slab using the same,

The present invention relates to a precast concrete deck for a long-span slab and a slab using the precast concrete slab, wherein a plurality of ribs are formed in a spanwise direction on the top of the bottom plate, the precast concrete deck comprising a plurality of first stranded wires A precast concrete deck for a long-span slab having at least one second strand shorter than the first strand so as to penetrate the rib, wherein a negative bending moment generated at both ends is reduced, and a slab using the same will be.

The floor of the horizontal form of the structure is referred to as a slab and is usually constructed in the form of a concrete slab. The concrete slab is generally composed of a composite structure of reinforcing bars, strands and the like, which are tensile materials, in order to complement concrete that functions as a compression material.

Generally, the concrete slab is formed by molding concrete and casting concrete after casting the reinforcing steel. In recent years, a deck plate integrated with a form and a truss girder is placed between the beams, and concrete .

However, the above methods have been uneconomical in terms of construction such as transportation and installation of materials, large amount of concrete pouring and curing, prolonged construction period due to deformation of formwork, and increase in construction cost. Precast concrete panels (PC panels) are used to fill the site with a small amount of on-site cast concrete after assembling the finished materials on site, A slab method is proposed.

The slab method using the PC panel can be classified into 'Ribbed Slab method', 'Hollow core method', 'Double T method' and 'Rib Plus method' depending on the type of the PC panel.

The 'Double T method' as shown in FIG. 1 is a method which is advantageous for slab construction between long and short sides by forming a pair of ribs at the lower part of the PC panel. However, it is very heavy and requires a paver for pouring concrete, There is a problem that the lower aesthetic tube is not beautiful due to the ribs formed in the bottom plate.

Meanwhile, the 'Ribbed Slab method' is disclosed in Korean Patent No. 10-0694587 (hereinafter referred to as "Prior Art Document 1", Dec. 13, 2006) and Korean Patent No. 10-1441515 (Hereinafter referred to as "Document 2", registered on Apr. 11, 2014), and a technique of placing a pre-stressed PC panel on which a reinforcing rib is formed and placing a topping concrete on the top to complete a slab However, it has to be manufactured using expensive automation equipment, and there is a problem that the amount of concrete placed on the spot increases.

In addition, the 'Hollow core method' has a plurality of hollows in the direction of the span, and can be applied to long distances of 10 m or more. In addition, when the upper concrete is poured, Is expensive.

Meanwhile, the 'Rib Plus method' described in Korean Patent No. 10-1152270 (hereinafter referred to as 'Prior Art Document 3', registered on May 25, 2012) forms a plurality of rows of hollow portions in the spanwise direction, And related technologies using a prestressed PC panel have been proposed.

The above-mentioned PC panels are completed by preliminarily stretching a stranded wire and curing the concrete after curing the strand, and introducing a prestress is performed by a long line pre-tensioning method, so that it is advantageous to manufacture a large number of products at a time .

However, in manufacturing the PC panel, since the prestressing method in which the strand is preliminarily tensioned and the concrete is laid is arranged in a straight line, the bending moment of negative (-) due to the eccentric arrangement of the strand in the PC panel .

In other words, the PC panel has a simple support structure due to the occurrence of a predetermined rise when the prestress is introduced due to the stranded wire arranged eccentrically from the center of the cross section, and the cross sectional force due to its own weight acts on the central portion, No cross-sectional force is generated at the supporting portions at both ends.

In the production of the PC panel by prestressing, the stiffness of the strand increases linearly with the transmission length (lt) as shown in FIG. 2 due to the wedge action at the end and the adhesion between the concrete and the strand , A certain negative bending moment due to the stranded wire is generated after the transmission length (lt).

At this time, it is important to simultaneously design the bending moment of positive (+) due to its own weight or load and the bending moment of negative (-) due to prestressing so as not to exceed the flexural crack strength. In the center part of the span direction, the bending moments cancel each other and do not exceed the bending strength. However, at both ends, the positive bending moment is weak and the bending strength can be exceeded.

In the slab method using the PC panel according to the prior art documents 1 to 3 disclosed in Figs. 2 to 4, in order to prevent such a phenomenon, the bending moment of the negative (-) generated at the ends is bent Method, a method of disposing an additional strand of strand or a method of partially unstacking a strand of strand.

However, the method of bending and arranging the stranded wire requires a separate direction switching device, which increases the cost of the prestressing and increases the risk of the operation.

In addition, the method of additionally arranging the stranded wire in the upper part generates the eccentric moment in the opposite direction to the strand disposed at the lower part of the upper part of the PC panel to reduce the bending moment at the end part. However, There is a problem that the effect is reduced and additional strand is required.

In addition, by covering a part of the strand provided at the end with a physical material such as tape or PC pipe, it is possible to prevent adhesion of concrete and strand to prevent transmission of tension, It is possible to prevent corrosion due to moisture penetration into the pores between the metal plates and the steel plate because the steel plate does not act as a structural member since the effect of adhesion of the stranded wires does not occur even after completion of the structure. .

SUMMARY OF THE INVENTION It is an object of the present invention to provide a precast concrete deck for a long-span slab, in which a negative bending moment generated at both ends is reduced so as not to exceed a flexural crack strength, Of the pre-cast concrete deck and the pre-casting of the cast-in-place concrete in order to prevent a sudden change in cross-section at both ends, The present invention provides a precast concrete deck for a long-span slab and a slab using the precast concrete deck.

In order to achieve the above object, a precast concrete deck (PCD) for a long-span slab according to the present invention comprises a bottom plate portion 10 having a predetermined thickness and a rectangular shape elongated in a spanwise direction, A plurality of ribs 20 are formed in the spanwise direction on the upper portion of the ribs 20 so that a hollow weight reduction portion 30 is integrally formed between the ribs 20 and a plurality of stranded wires R (PCD) in which a plurality of ribs (20) are integrally connected to upper ends of both end portions in the spanwise direction of the bottom plate portion (10) And the rib connecting portion 40 removes a part of the concrete of the rib connecting portion 40 at a position corresponding to the plurality of ribs 20 so as to provide a space at the upper portion of the bottom plate portion 10, The portion 41 A plurality of rib break portions 41 are integrally formed with the partition wall portions 42 so as to penetrate the bottom plate portion 10 at a lower portion of the ribs 20, And at least one second strand R2 shorter than the first strand R1 so as to be exposed through the rib 20 through the rib 20 at the upper portion of the first strand R1, (-) bending moment generated at both ends is reduced.

delete

An end wall portion 43 is formed between the rib 20 and the rib disconnecting portion 41 of the rib connecting portion 40. Both end portions of the second strand R2 are connected to the end wall portion 43, As shown in FIG.

The rib disconnecting portion 41 of the rib connecting portion 40 is formed to open to the outside and extends from the view portion 41a formed on the side of the end wall portion 43 to the end portion 41b opened outwardly, Can be gradually formed to have a fan shape.

The length L in the spanwise direction of the ribs 41 of the rib connection part 40 may be less than a transfer length.

The rib portion 40 of the rib connection portion 40 may have a fan shape so that the width of the rib portion 40 gradually narrows from the view portion 42a formed on the inner side to the end portion 42b formed on the outer side.

The width Siw of the view portion 42a of the partition wall portion 42 may be equal to or larger than a minimum value? Rw / (n-1).

The width Siw of the partition 42 may be equal to or less than a maximum value Dw -? Rw / (n-1).

The width Sfw of the end portion 42b of the partition 42 may be equal to or greater than the width Rw of the center rib 20.

On the other hand, the precast concrete slab for long-span slab of the present invention is formed by placing a precast concrete deck (PCD) on an upper part of a beam G of a structure S and placing concrete thereon, (PCD) is mounted on the upper portion of the beam G and is simultaneously mounted on the rib disconnecting portion 41 of the precast concrete deck PCD adjacent to the rib disconnecting portion 41 of the rib connecting portion 40 in the spanwise direction. (60), and on-site concrete (70) is provided on the upper part of the beam (G) and the upper part of the precast concrete deck (PCD).

The precast concrete deck for long-span slab of the present invention is characterized in that a plurality of first stranded wires passing through a bottom plate portion are fixed, at least one second stranded wire passing through the ribs is shorter than the first stranded wire, (-) bending moment generated is reduced so that the flexural crack strength is not exceeded, and the occurrence of cracks can be prevented.

Since the second strand is adhered by the required length at both ends, it is possible to control the amount of bending moment generated by the prestressing at the end, so that the amount of the prestress introduced at the center of the maximum sectional force generating portion can be increased It is possible to arrange the first strand at the maximum.

Further, the ribs are gradually narrowed in width from the viewpoint formed on the side of the end wall to the endpoint of the end opened to the outside, so that the ribs have a fan shape, and the stiffness changes as a sudden change in the cross- It is possible to solve the problem that stress is concentrated and cracks are generated.

Also, because of the shape of the partitions, the amount of high-strength concrete required for manufacturing the precast concrete deck can be reduced, and the workability can be ensured by providing the connection reinforcing bars.

In addition, in the process of manufacturing the precast concrete deck, it is possible to flexibly adjust the amount of prestressing of the second strand exposed in the rib cut-off portion, and to secure a work space for cutting the strand.

In addition, a connection reinforcing bar is provided to be simultaneously mounted on the rib-connecting portion of the rib connecting portion and the rib-breaking portion of the precast concrete deck adjacent to the rib connecting portion in the spanwise direction. The effect can be sufficiently secured.

1 is a sectional view showing a PC panel used in the 'Ribbed Slab method', the 'Hollow core method', and the 'Double T method' according to the related art.
Figs. 2 to 4 are diagrams showing a general PC panel according to the prior art documents 1 to 3. Fig.
5 shows the bending moment according to the general arrangement of the strand.
6a and 6b are a perspective view and a perspective projection view of a pre-cast concrete deck with an open top according to an embodiment of the present invention;
FIGS. 6C to 6E are a longitudinal section view, a width direction section view, and a widthwise elevation view of a pre-cast concrete deck having an open top according to an embodiment of the present invention.
7 is a perspective view showing a pre-cast concrete deck having an open top according to another embodiment of the present invention.
8A and 8B are a perspective view and a perspective view showing a precast concrete deck in which an upper part is closed according to an embodiment of the present invention.
FIGS. 8C to 8E are a longitudinal section view, a widthwise section view, and a widthwise elevation view, respectively, of a pre-closure pre-cast concrete deck according to an embodiment of the present invention.
FIG. 9 is a perspective view showing a pre-cast concrete deck according to another embodiment of the present invention. FIG.
10A and 10B are views for explaining the construction of a precast concrete deck for a long-span slab according to an embodiment of the present invention.
11 is a bending moment diagram according to an arrangement of stranded wires in an embodiment of the present invention.
12 is a bending moment chart showing the relationship between the length L in the spanwise direction of the rib cut-off portion and the transmission length ll according to the present invention.
13 is a conceptual view showing a construction section of a precast concrete slab for a long-span slab according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a sectional view sequentially showing a PC panel (Precast Concrete Panel) used in the 'Ribbed Slab Method', the 'Hollow Core Method' and the 'Double T Method' according to the related art. And the ribs 2 are formed on the upper and lower portions to increase the sectional force.

Particularly, in the PC panel used in the hollow core method, since the hollow portion 3 is integrally formed between the ribs 2, it is possible to secure a sufficient sectional force while partially removing the concrete, thereby reducing the self weight at the time of transportation .

At this time, a stranded wire is provided on the inside of the ribs 2 so as to secure a tensile force. Further, the vertical reinforcing bars 5 are continuously arranged along the ribs 2 in a spiral direction, And the synthesis effect with concrete is promoted.

The PC panels are produced as a finished product by applying a tensile force to a pre-stiffened strand at a factory, and then pouring concrete, and a conventional PC panel is produced by this pretension method.

At this time, since the PC panels are arranged in a straight line by the characteristics of the pretension method, a negative bending moment due to the eccentric arrangement of the stranded wire is generated in the PC panel, and the positive (+) bending It is offset by the moment.

However, as shown in FIG. 5, the bending moments of the center portion in the spanwise direction are offset from each other and do not exceed the bending strength. However, the positive bending moments at both ends are weak and the bending strength may exceed the bending strength. .

2 to 4, since stranded wires provided on the ribs 2 are attached from both ends of the PC panel, in order to solve the above-mentioned problem, the stranded wires are bent and arranged, The method of reducing the bending moment generated in the strand, the method of disposing an additional strand of strand in the strand, or the method of non-sticking the strand of strand at a certain portion.

Meanwhile, the precast concrete deck (PCD) shown in FIGS. 6A to 6B has a shape according to an embodiment of the present invention and is the same as the PC panel used in the conventional 'Ribbed Slab method' and 'Hollow core method' A plurality of ribs 20 are formed in the spanwise direction on the bottom plate 10 to form a plurality of ribs 20 between the ribs 20, Respectively, and a plurality of stranded wires R are passed in the spanwise direction to apply tensile force in advance.

Meanwhile, the precast concrete deck (PCD) of the present invention may also include a horizontal reinforcing bar (HR) and a vertical reinforcing bar (VR). The horizontal reinforcing bars HR and the vertical reinforcing bars VR are provided on the ribs 20 and prevent the cracks which may occur during manufacture or transportation like the conventional PC panels, ) Is partially exposed so as to achieve a composite effect with the cast concrete.

In this case, the vertical reinforcing bars (VR) may be manufactured in various shapes and continuously arranged in the spanwise direction. The vertical reinforcing bars (VR) may be formed as a mountain-shaped member as shown in FIGS. 6A to 6B, They can be made of the same Z-shaped member and arranged continuously.

In addition, the pre-cast concrete deck (PCD) is formed with grooves (GR) in the widthwise side and continuous along the spanwise direction, so that the composite effect of the girder and the precast concrete deck Can be increased.

At this time, as shown in FIGS. 8A to 8B and 9, the upper plate 50 is additionally formed on the ribs 20 and the hollow weight reduction portion 30, so that the PC panel Or the like.

6D and 8D, the precast concrete deck (PCD) of the present invention may be constructed so that the on-site poured concrete 70 is embedded in the weight reducing portion 30, or a separate weight reducing material 31). As the weight loss reducing material 31, a heat insulating material or a sound insulating material of a synthetic resin material may be used, and foamed styrofoam, urethane or the like may be applied specifically.

6C to 6E, the present invention is characterized in that at least one first strand R1 is fixed to the bottom of the rib 20 so as to penetrate the bottom plate 10, and the first strand R1 And fasten at least one second strand R2 shorter than the first strand R1 so as to penetrate the rib 20 at the top of the first strand R2.

11 is a bending moment according to the arrangement of stranded wires according to an embodiment of the present invention in which a relatively negative bending moment is reduced by a cut length d formed to be shorter than the first strand R1 As a result, it is possible to prevent the occurrence of negative bending moments exceeding the flexural crack strength, despite the occurrence of a relatively weak positive bending moment at both ends.

As a result, the present invention reduces the negative bending moment generated at both ends and does not exceed the flexural crack strength, thereby preventing the occurrence of cracks.

6A, 8A, and the like, rib connecting portions 40 are formed on upper portions of both ends in the spanwise direction of the bottom plate 10 so that the plurality of ribs 20 are integrally connected to each other in a direction perpendicular to the spanwise direction As shown in FIG.

 The rib connection part 40 removes a part of the concrete of the rib connection part 40 at a position corresponding to the plurality of ribs 20 so that a rib cut part 41 is formed so as to provide a space above the bottom plate part 10 And a plurality of these can be formed.

The position corresponding to the rib 20 in which the rib cut-off portion 41 is formed is defined as a position in which the central axis in the width direction of the rib cut-off portion 41 is located on the extension of the central axis in the width direction of the rib 20, It is preferable that the ribs 20 and the ribs 41 are formed in the same number n.

At this time, a partition wall portion 42 is integrally formed between the plurality of rib disconnection portions 41, and the number of the partition wall portions 42 is (n-1). On the other hand, the second strand R2 is exposed and fixed by the rib cut-off portion 41 so that the position where the second strand R2 is fixed is located inside the position where the first strand R1 is fixed , The negative bending moment generated at both ends can be reduced.

An end wall portion 43 may be formed between the rib 20 and the rib disconnecting portion 41 of the rib connecting portion 40. More specifically, both end portions of the second strand R2 may be connected to the end wall portion 43, respectively.

10A and 10B, the end wall portion 43 is defined as being continuous in the width direction. The partition wall portion 42 is integrally formed with the end wall portion 43, The view portion 42a of the partition wall portion 42 starts from the outside of the end wall portion 43 and the end portion 42b of the partition wall portion 42 is formed on the extension line of the span- ) Is located.

The rib disconnecting part 41 of the rib connecting part 40 is open to the outside and extends from the view part 41a formed on the side of the end wall part 43 to the end part 41b, Can be formed to be gradually wider and have a fan shape.

At this time, by forming the rib cut-off portion 41 of the rib connecting portion 40, it is possible to flexibly adjust the amount of prestressing of the second stranded wire exposed in the rib cut-off portion in the process of manufacturing the precast concrete deck, It is possible to secure a work space for cutting work.

It is preferable that the length L in the spanwise direction of the rib cutout portion 41 of the rib connection portion 40 is less than the transfer length lt.

12 is a bending moment diagram showing the relationship between the length L in the spanwise direction of the rib cut-off portion 41 and the transmission length ll according to the present invention. As shown in the figure, the rib- When the length L exceeds the transmission length < RTI ID = 0.0 > (lt), < / RTI >

Therefore, when the length L in the spanwise direction of the rib cut-off portion 41 does not exceed the transmission length lt, it is preferable that the cut portion is not generated as in (b).

At this time, the transfer length (lt, transfer length) can be calculated by the following equation.

lt (transmission length) = 1.6 (0.15 fps-0.1 fpe) dB

fps: average stress of tensile material (MPa)

fpe: effective stress of tensile material after all losses occur (MPa)

db: Nominal diameter of strand

Also, when the stiffness is rapidly changed to the point where the cross section of the precast concrete deck (PCD) is abruptly changed, the partition wall portion 42 may be a cause of cracks due to concentration of stress. Therefore, in order that the sectional rigidity of the concrete is continuously maintained in the partition wall portion 42 and the end portion 42b opened outward from the viewpoint portion 42a formed on the side of the end wall portion 43 so as to avoid a sharp change in stress, Is formed so as to be gradually narrowed so as to have a fan shape.

At this time, the rib cutout portion 41 of the rib connection portion 40 is also formed to have a fan shape. Specifically, the width from the viewpoint portion 41a to the end portion 41b formed on the outer side is gradually widened to have a fan shape.

Thus, the amount of high-strength concrete used for manufacturing the precast concrete deck can be reduced, and the workability can be secured by providing the connection reinforcing bars 60 to be described later.

The width Siw of the view portion 42a of the partition wall portion 42 is preferably at least ΣRw / n-1.

This is because a sufficient sectional force can be ensured if the sum of the total cross sectional width of the plurality of (n) ribs 20 and the cross sectional width of the view portion 42a of the partition 42 is at least equal to or greater than the sum of the cross sectional widths. (? Rw: a sum of the widths (Rw) of a plurality of (n) ribs, Dw: width of the deck)

At this time, the rib 20 defines a distance Rw between the two vertical lines that are most spaced in the width direction.

It is preferable that the width Siw of the view portion 42a of the partition wall portion 42 is equal to or less than a maximum value Dw -? Rw / n-1. (Dw: width of deck)

This is because the width Rw of the ribs 20 must be greater than or equal to the width Rw of the joints of the beam and the precast concrete deck in order to secure sufficient strength when the cast concrete 70 is laid.

However, it is preferable that the width Sfw of the end portion 42b of the partition 42 is equal to or greater than the width Rw of the rib 20 located at the center. In order to ensure workability such as the placement of the placed concrete 70 and the connecting reinforcing bars 60 and to ensure a sufficient sectional force at both ends in the span direction where the shear force is greatest, Rw) or less.

On the other hand, a precast concrete slab (PCS) formed by placing a precast concrete deck (PCD) on the upper part of a beam G of the structure S and casting concrete thereon has the following structure.

13, the precast concrete deck (PCD) of the present invention is mounted on the upper part of the beam G, and the pre-cast concrete deck PCD The ribs 60 are provided on the ribs 41 at the same time.

At this time, the precast concrete slab of the present invention is completed by providing the cast concrete (70) on the upper part of the beam (G) and the upper part of the precast concrete deck (PCD).

At this time, the connection reinforcing bar 60, which is fixed to the rib cut-off portion 41, is disposed on the extension line of the rib 20. When the horizontal reinforcing bar HR of the precast concrete deck is protruded, There is an advantage that continuous joining is possible in the spanwise direction by binding with the reinforcing bars 60. [

The precast concrete deck for a long-span slab according to the present invention and the slab using the same are not limited to the above-described embodiments, and various modifications and changes may be made without departing from the spirit and scope of the present invention, It should be understood that the present invention falls within the scope of the claims of the present invention to the extent that any person skilled in the art will be able to variously modify and carry out the invention.

PCD: Precast Concrete Deck S: Structure
G: girder HR: horizontal reinforcement
VR: vertical reinforcement GR:
R1: 1st strand R2: 2nd strand
10: bottom plate part 20: rib
30: Self weight reduction part 31: Self weight reduction material
40: rib connecting portion 41: rib cutting portion
41a: viewpoint portion 41b: endpoint portion
42: partition wall portion 42a:
42b: end point portion 43:
50: upper plate portion 60: connecting reinforcing bar
70: Field cast concrete

Claims (10)

A plurality of ribs 20 are formed in the spanwise direction on the bottom plate 10 to form a plurality of ribs 20 between the ribs 20, (PCD) in which a hollow weight reduction portion (30) is integrally formed in a spanwise direction and a plurality of strands (R)
A rib connection portion 40 is formed in a direction perpendicular to the span so that the plurality of ribs 20 are integrally connected to both ends in the spanwise direction of the bottom plate portion 10. The rib connection portion 40 includes a plurality of ribs 20, A plurality of rib cut-off portions 41 are formed so that a space is formed at an upper portion of the bottom plate portion 10 by removing a part of the concrete of the rib connecting portions 40 at positions corresponding to the ribs 20, And at least one first strand R1 is fixed to the bottom of the rib 20 so as to penetrate the bottom plate 10, and the first strand < RTI ID = 0.0 > At least one second strand R2 shorter than the first strand R1 is fixed to the ribs 20 through the ribs 20 so as to be exposed to the ribs 41, And the bending moment of the long-span slab is reduced Ritdeck.
delete The method according to claim 1,
An end wall portion 43 is formed between the rib 20 and the rib disconnecting portion 41 of the rib connecting portion 40. Both end portions of the second strand R2 are fixed to the end wall portion 43 Wherein the pre-cast concrete deck for a long-span slab.
The method of claim 3,
The rib disconnecting portion 41 of the rib connecting portion 40 is formed to be open to the outside and the width of the rib connecting portion 40 gradually increases from the viewpoint portion 41a formed on the side of the end wall portion 43 to the end point portion 41b opened outwardly Wherein the pre-cast concrete deck has a fan shape.
5. The method of claim 4,
Wherein the rib severing part (41) of the rib connection part (40) is formed such that the spanwise length (L) is equal to or less than the transmission length (lt, transfer length).
fpe is the effective stress (MPa) of the tensile material after all losses occur (dB), fpe is the effective stress (MPa) of the tensile material after all losses occur, and db : Nominal diameter of strand]
5. The method of claim 4,
The partition wall portion 42 of the rib connection portion 40 is formed gradually narrower from the viewpoint portion 42a formed on the inner side to the end portion 42b formed on the outer side so as to have a fan shape. Precast Concrete Deck.
The method according to claim 6,
Wherein a width Siw of the view portion 42a of the partition wall portion 42 is at least? Rw / n-1.
[? Rw: a value obtained by adding together the widths (Rw) of plural (n) ribs]
The method according to claim 6,
The precast concrete deck for a long-span slab according to any one of the preceding claims, wherein a width (Siw) of the view portion (42a) of the partition portion (42) is equal to or smaller than a maximum (Dw -? Rw) / (n-1).
[Dw: width of deck]
The method according to claim 6,
Wherein the width Sfw of the end portion 42b of the partition wall portion 42 is equal to or greater than the width Rw of the rib located at the center of the pre-cast concrete slab.
In a precast concrete slab (PCS) formed by placing a precast concrete deck (PCD) on the upper part of a beam G of a structure S and placing concrete thereon,
(PCD) of the pre-cast concrete deck (PCD) of claim 1 is mounted on the upper part of the beam G and the ribs 41 of the pre-cast concrete decks PCD adjacent to the rib- And a cast concrete slab (70) is provided on the top of the beam (G) and on top of a precast concrete deck (PCD) Concrete slabs.

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