KR102415136B1 - Optimized two-way precast concrete block slab - Google Patents

Abstract

The disclosed content is optimized to reduce the weight of the slab so that the disadvantages of the conventional MRS and H/S can be compensated, the interconnection of the slab can be easily and robustly made, and the field work can be minimized by reducing the amount of rebar installed It relates to a bidirectional precast concrete block slab.
The disclosed content includes a precast concrete block for slab in which wing portions extend to a thickness smaller than that of the central portion on both sides of a central portion extending in the longitudinal direction with a predetermined width, and a horizontal connector installed horizontally in the precast concrete block for slab. and a lightweight material block inserted and installed along the longitudinal direction in the central portion of the precast concrete block for the slab and spaced apart from each other at a predetermined interval, and the lightweight material block to be positioned in the central portion of the precast concrete block for the slab An optimized bi-directional precast concrete block slab including vertical reinforcing bars embedded in the longitudinal direction is presented as an example.

Description

Optimized bidirectional precast concrete block slab {OPTIMIZED TWO-WAY PRECAST CONCRETE BLOCK SLAB}

The disclosed content relates to a precast concrete block slab, and more particularly, to a bidirectional precast concrete block slab designed so that a load acting vertically, such as a fixed load or a loaded load, is transmitted in both directions, that is, in the short side direction and the long side direction. will be.

Unless otherwise indicated herein, the contents described in this identification are not prior art to the claims of this application, and the description in this identification is not admitted to be prior art.

In general, the Precast Concrete (hereinafter referred to as PC) construction method refers to a construction method in which a reinforced concrete structure constructed at the site is divided (pillar, beam slab) at a factory, manufactured, and brought into the site to build the structure in a prefabricated manner. .

Recently, with the development of construction technology, as interest and importance in cost reduction, quality improvement, construction stability improvement, economic feasibility assurance, and period shortening have increased, the PC method is also in a continuous development trend.

This PC method is applied to many factories and buildings as well as wastewater treatment plants, underground parking lots, and apartment houses.

Here, the construction sequence of the PC method is as shown in FIG. 1 , first, a PC column is installed, and then a PC girder is installed according to the PC column, then a PC slab is installed, and a topping concrete is finished. This is done by pouring The slab construction according to the PC method is generally similar, but only the shape is different for each slab type.

The above-described PC slab is applied according to the structure or characteristics of the building, and is divided into a lower rib-type PC slab and a lower flat-type PC slab.

Compared to the lower rib type PC slab, which has a protruding rib at the bottom, the lower flat type PC slab has a flat structure at the bottom. It has advantages and is used in various fields.

One of the lower rib type PC slabs, DTS (Double Tee Slab, hereinafter referred to as DTS), is a slab advantageous for long-span design. It has the advantage of excellent shear resistance and easy assembly. However, since the DTS method is designed as a simple beam, there is a risk of cracking.

Next, MRS (Multi Rib Slab, hereinafter referred to as MRS) is designed as a continuous slab in order to solve the cracking problem occurring in DTS as a method advantageous for long span as shown in FIG. First, the factory produces a slab up to a certain height, brings it to the site, installs it, and then constructs the structure. In addition, MRS has the advantage of excellent shear resistance and synthesis ability of PC members by producing the top exposed shear reinforcement.

However, MRS (Multi Rib Slab, hereinafter referred to as MRS) has the disadvantage of having a large amount of work for reinforcing the upper and lower rebars on site, and the existence of ribs may cause damage to the ribs while installing mechanical equipment, and there is a problem of collapse. do.

In addition, H/S (Half Slab, hereinafter referred to as H/S) among the flat type PC slabs, as shown in FIG. 3, produces slabs up to a certain height in a factory, transports them to the installation site, and installs them, similarly to MRS, to form a structure. will be built

Since the H/S method is a flat type rather than a rib, there is no interference when working with machinery or equipment under it, and the efficiency is increased during lower waterproofing work, and there is no need for a formwork. In addition, on the other hand, there is no need for a separate shear reinforcing bar, the width can be changed freely, and the on-site management is simple and quality control is easy. However, it is necessary to use a horizontal plate-plate reinforcing bar to be reinforced at the site. There is a problem that interference occurs during reinforcing bars. In addition, the amount of reinforcement in the slab increases and when it is installed with a non-steel wire, the beam becomes oriented in two directions, which can lead to an increase in the amount of PC. In addition, in the case of a long span design, cracks and sags increase and the cross section becomes large.

Therefore, in order to compensate for the shortcomings of MRS and H/S among these PC slabs, a PC slab that can reduce the weight of PC slab members and the amount of concrete, minimize field work, and reduce the amount of reinforcing bars to reduce construction costs. need to provide

The weight of the slab is reduced so that the shortcomings of the conventional MRS and H/S can be compensated, the interconnection of the slab can be easily and robustly made, and the optimized bidirectional freewheel can minimize field work by reducing the amount of rebar installed We would like to provide cast concrete block slabs.

In addition, it is not limited to the technical problems as described above, and it is obvious that another technical problem may be derived from the following description.

The disclosed content includes: a precast concrete block for a slab in which wing portions extend to a smaller thickness than the central portion on both sides of the central portion extending in the longitudinal direction with a predetermined width; a horizontal connector installed horizontally in the precast concrete block for the slab; a lightweight material block inserted and installed along the longitudinal direction in the central portion of the precast concrete block for the slab and spaced apart from each other at a predetermined interval; And an optimized bidirectional precast concrete block slab, characterized in that it includes a vertical reinforcing bar embedded in the longitudinal direction in the central portion of the precast concrete block for the slab to be positioned between the lightweight material blocks. .

According to a preferred feature of the disclosure, the central portion of the precast concrete block for the slab includes a space portion into which the lightweight material block is inserted, and a rib partitioning the lightweight material block (eg, EPS block, etc.) to be spaced apart from each other. include

According to a preferred feature of the disclosed content, the longitudinal length of the lightweight material block is less than or equal to the longitudinal length of the space portion, and the lightweight material block is inserted and disposed in the center of the space portion.

According to a preferred feature of the disclosure, the horizontal connecting muscle includes an embedded part installed horizontally across the central part and the wing part of the precast concrete block for slab, and rises so as to be inclined to a predetermined height from one end of the wing part. It includes an extended inclined portion, and an extension formed extending from the upper end of the inclined portion in the horizontal direction again.

According to a preferred feature of the disclosure, the extension portion of the horizontal connector is located above the wing portion of the neighboring precast concrete block for slab.

According to a preferred feature of the disclosure, the horizontal connector is installed horizontally across the central portion and the wing portion of the precast concrete block for slab, and the wing portion of the precast concrete block for slab and the adjacent slab. The connecting wire mesh is embedded and fixed on the wing of the precast concrete block for concrete pouring.

According to a preferred feature of the disclosure, the vertical reinforcing bars are arranged in a zigzag vertical direction along the longitudinal direction of the precast concrete block for slab in a direction perpendicular to the horizontal connecting reinforcing bars.

According to a preferred feature of the disclosure, the upper end of the vertical reinforcing bar protrudes outward from the upper portion of the central portion of the precast concrete block for the slab.

According to a preferred feature of the disclosure, the upper end of the vertical reinforcing bar is bent in a zigzag shape to increase in-plane shear resistance and vertical shear resistance.

According to a preferred feature of the disclosure, it further includes a wire mesh that is installed horizontally in the precast concrete block for the slab so as to be located on the upper portion of the lightweight material block.

According to the optimized bidirectional precast concrete block slab according to an embodiment of the disclosed content, there are advantages in that the disadvantages of the conventional MRS and H/S are supplemented, field work is minimized, and the amount of reinforcing bars is reduced.

In addition, according to the optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure, as the horizontal connector is installed in the precast concrete block for the slab, the horizontal plate installed in the existing half slab - even without installing the plate reinforcement has the advantage of being

In addition, according to the optimized bi-directional precast concrete block slab according to an embodiment of the disclosed content, when the slab becomes higher than a certain height in the existing half slab, the disadvantage of having to install additional corrugated reinforcing bars for upper reinforcement can be solved. there is

In addition, according to the optimized bidirectional precast concrete block slab according to an embodiment of the disclosure, the overall construction cost is reduced by reducing the thickness of the wing of the precast concrete block for the slab compared to the half slab, and the precast for the neighboring slab As the depth of concrete poured into the joint section of the concrete block increases, the watertightness increases, and the amount of on-site reinforcing bars is minimized by increasing the effective D value when calculating the structure.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a construction schematic diagram by a general precast concrete construction method.
2 is a cross-sectional view of a precast concrete block for a slab according to the MRS method.
3 is a cross-sectional view of a precast concrete block for a slab according to the H/S method.
4 is a partially cut-away perspective view of an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure;
5 is a cross-sectional view of an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure;
6 is an installation state diagram of a lightweight material block and a horizontal connector in the optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure;
7 is a connection structure diagram of a precast concrete block for a slab using a connecting wire mesh in the optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure;
8 is a comparison diagram of PC and RC quantities with H/S in the optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure;
9 is a plan view and longitudinal cross-sectional view of an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure;
10 is a comparison view with H/S in the process of installing an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure;

Hereinafter, the configuration, operation, and effect of the preferred embodiment will be described with reference to the accompanying drawings. For reference, in the following drawings, each component is omitted or schematically illustrated for convenience and clarity, and the size of each component does not reflect the actual size. In addition, the same reference numerals refer to the same components throughout the specification, and reference numerals for the same components in individual drawings will be omitted.

First, the optimized bi-directional precast concrete block slab according to an embodiment of the present disclosure is constructed by the precast concrete method.

In the construction method by the precast concrete method, as shown in FIG. 1 , a PC column is initially installed, and a PC girder for interconnecting the PC column is installed. Then, a plurality of precast concrete blocks for slabs assembled between PC girders are installed, and the topping concrete is poured as a finish.

Precast concrete blocks for slabs applied to the precast concrete construction method are variously applied according to the structure, characteristics, and construction methods of buildings, and the present disclosure intends to present improved forms of MRS and H/S.

First, as shown in FIG. 2, MRS (Multi Rib Slab, hereinafter referred to as MRS) is a method advantageous for long spans, and is designed as a continuous slab to solve the cracking problem. It is carried out in a way that the structure is constructed by bringing it into the site, installing it, and making the lower part of the slab a rib to increase the efficiency of the PC section.

In addition, it has the advantage of excellent shear resistance and composite ability of the PC member due to the purchase of shear reinforcing bars. , there is a disadvantage in that the lower part of the slab is made of ribs and the waterproof workability is deteriorated.

Here, the upper and lower reinforcing bars are rebars applied to the precast concrete block for slabs, and they resist bending tension together with the concrete and are reinforcing bars that respond to all forces acting on the precast concrete block for slabs, such as shear force or torsion. .

These reinforcing bars are divided into upper reinforcing bars and lower reinforcing bars. The lower reinforcing bar is a reinforcing bar placed for the purpose of reinforcing the bending moment tensile force generated from the bottom, and the upper rebar is a reinforcing bar disposed for the purpose of reinforcing the bending moment tensile force generated from the upper side.

Referring to FIG. 3, among the flat type PC slabs, Half Slab produces precast concrete blocks for slabs up to a certain height in the factory, transports them to the installation site, and installs them to construct the structure.

Since the half slab method is a flat type, not a rib, there is no interference when working with machinery or equipment under it, and it has the advantage of increasing the efficiency when working on the lower part of the waterproofing. In addition, shear reinforcing bar means reinforcing bars used to prevent shear fracture due to shear cracking, which has the advantage that such a shear reinforcing bar is not required. There is a problem that interference occurs when reinforcing the RC upper reinforcing bars in the section where shear reinforcing bars are required. In addition, in the case of a long span design, cracks and sags increase and the cross section becomes large.

4 is a partially cut-away perspective view of an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure, and FIG. 5 is a cross-sectional view of an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure; 6 is a diagram illustrating an installation state of a lightweight material block and a horizontal connector in an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure, and FIG. 7 is an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure. In the precast concrete block slab, it is a connection structure diagram of the precast concrete block for the slab using the connecting wire mesh.

The optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure has wings 13 on both sides of the central portion 11 extending in the longitudinal direction with a predetermined width as shown in FIGS. 4 to 7 . A precast concrete block 10 for slab extending to a thickness smaller than the central portion 11, a horizontal connector 20 embedded horizontally in the precast concrete block 10 for slab, and a precast concrete block for slab Precast concrete blocks for slabs are inserted and installed along the longitudinal direction in the central part 11 of (10) so that they are positioned between the lightweight material blocks 30 and the lightweight material blocks 30, a plurality of which are spaced apart from each other at a predetermined interval. It includes a vertical reinforcing bar 40 that is embedded in the central part 11 of (10) along the longitudinal direction.

Here, it is preferable that the precast concrete block 10 for the slab is composed of a flat PC slab, and a central portion 11 extending in the longitudinal direction with a width corresponding to a general half slab, and the central portion 11 are installed on both sides. Doedoe may include a wing portion 13 that extends to have a smaller thickness than the central portion (11).

The width of the wing 13 may be composed of the width of the length of the shoyo reinforcing bar, and the thickness of both sides of the precast concrete block 10 for the slab is increased due to the relatively thin wing 13 having a thickness. As it is reduced, the PC quantity can be reduced compared to the conventional H/S.

That is, the conventional H/S has a quantity of PC having a predetermined thickness and a quantity of concrete poured on it, but the precast concrete block 10 for a slab of the disclosed content is relatively small extending on both sides of the central part 11 . The PC quantity is reduced compared to H/S by the thickness of the wing part 13 .

In addition, in the case of pouring concrete on the upper part after interconnecting a plurality of precast concrete blocks 10 for slabs, the thickness of the wing 13 is thin compared to H/S for a plurality of precast concrete blocks for slabs (10) The quantity of concrete (RC (Reinforced Concrete) quantity) poured into the joint section between (10) becomes relatively large. Accordingly, since the depth at which the RC is poured increases, in particular, in the case of a precast concrete block slab applied to a water treatment structure, there is an advantage in that the water resistance and watertightness of the joint section of the precast concrete block 10 for the slab is increased.

The horizontal connecting muscle 20 is horizontally connected across the central portion 11 and the wing portions 13 extending on both sides of the above-mentioned precast concrete block for slab 10, preferably, the precast concrete block for slab 10 in the horizontal direction. It is purchased and installed according to

The horizontal connecting reinforcing bar 20 not only corresponds to the reinforcing bar in the precast concrete block 10 for a slab, but also forms a base to which the vertical reinforcing bar 40 is connected, as shown in FIGS. 4 and 5, the slab The embedded part 21 that is installed horizontally through the central part 11 and the wing part 13 of the precast concrete block 10 for use, and the wing part 13 rises so as to be inclined to a predetermined height from one end of the wing part 13. It includes an inclined portion 23 extending to the slanted portion 23 and an extension portion 25 extending from the upper end of the inclined portion 23 in the horizontal direction again.

As shown in FIGS. 4 and 5, the embedded part 21 of the horizontal connector 20 is installed along the horizontal direction of the precast concrete block 10 for a slab, and from the wing part 13 on one side It includes an embedded part 21 that is installed horizontally through the central part 11 to the wing part 13 of the other side.

The inclined portion 23 of the horizontal connecting muscle 20 is formed to extend upward from one end of the wing 13 so that the horizontal connecting muscle 20 is exposed from the precast concrete block 10 for the slab to the outside. do.

In addition, as the extension part 25 of the horizontal connecting muscle 20 extends from the upper end of the inclined part 23 again in the horizontal direction, that is, parallel to the embedded part 21, as shown in FIG. 6 , the adjacent slab It extends onto the wing portion 13 of the precast concrete block 10 for use.

The horizontal connector 20 is formed from the embedded part 21 installed inside the precast concrete block 10 for the slab to the extension part 25 through the inclined part 23, thereby forming the precast concrete block for the slab ( 10) to be able to support the vertical load applied to it, and in particular, the extension part 25 is the wing part 13 of the neighboring precast concrete block 10a for a slab, preferably the adjacent wing part 13. The mutual bonding force between the neighboring precast concrete blocks 10 for slabs is increased by making them located on the upper side of the

More specifically, as shown in FIG. 6 , the extension part 25 of the horizontal connector 20 extending from the wing part 13 of the precast concrete block 10 for the slab is adjacent to the precast slab. As the concrete is poured on the upper side of the wing part 13 of the concrete block 10a and the bonding performance between the precast concrete blocks 10 and 10a for a slab is improved, unity can be achieved, and the bonding section cracks can be reduced.

In particular, in the conventional H/S, in a state in which the slabs are arranged to be adjacent to each other, it was necessary to provide reinforcement in the field using a plate-plate reinforcement in the horizontal direction, but a precast concrete block for a slab according to an embodiment of the disclosure. When the (10) is arranged adjacent to each other in turn, it is not necessary to separately reinforce the reinforcing bars in the field by the embedded horizontal connecting reinforcing bars 20, so that the on-site reinforcing work can be reduced. In addition, according to the example shown in FIG. 6, the joint length of the plate-plate reinforcing bar reinforced when interconnecting adjacent slabs by conventional H/S was required as long as twice the length of the joint disposed on each slab. In the context, even if only the length of the wing portion 13 of the precast concrete block 10 for a slab is disposed, there is sufficient bonding between the adjacent precast concrete blocks 10 and 10a for a slab, so the amount of reinforcing bars can be reduced.

In addition, as shown in Fig. 7, the horizontal connecting muscle 20 does not include the inclined portion 23 and the extended portion 25, but is horizontally across the central portion and the wing portion of the precast concrete block 10 for slab. Can be purchased and installed.

In this case, the connecting wire mesh 27 is embedded on the wing 13 of the precast concrete block 10 for slab and the wing 13 of the neighboring precast concrete block 10a for slab when pouring concrete. It is preferable to be fixed.

8 is a comparison view of PC and RC quantity with H/S in an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure, and FIG. 9 is an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure. It is a plan view and a longitudinal cross-sectional view of a precast concrete block slab, and FIG. 10 is a comparison view with H/S in the process of installing an optimized bidirectional precast concrete block slab according to an embodiment of the present disclosure.

In the central part 11 of the above-mentioned precast concrete block 10 for slab, the lightweight material block 30 is inserted and installed along the longitudinal direction, and a plurality of them are arranged spaced apart from each other at a predetermined interval. The lightweight material block 30 is for reducing the weight of the precast concrete block 10 for a slab, and for example, refers to a lightweight material for civil engineering with general ultra-light material properties, such as an EPS block.

As a plurality of lightweight material blocks 30 are spaced apart from each other at a predetermined interval in the central part 11 of the precast concrete block 10 for a slab, the compression resistance, water resistance, lightness, and workability of the precast concrete block 10 for a slab , the flame retardancy is increased.

As shown in FIG. 8, the central part 11 of the precast concrete block 10 for a slab so that the lightweight material block 30 can be arranged in the central part 11 of the precast concrete block 10 for a slab. , it is preferable to include a space portion 111 into which the lightweight material block 30 is inserted, and a rib 113 partitioning the lightweight material block 30 to be spaced apart.

The lengthwise length of the lightweight material block 30 is preferably less than or equal to the lengthwise length of the space portion 111 so that the lightweight material block 30 is inserted into the space portion 111 . In addition, the lightweight material block 30 extends in the same cross-section in the longitudinal direction as shown in FIG. 9 , and both ends of the lightweight material block 30 in the longitudinal direction are preferably tapered toward both ends of the space portion 111 in the longitudinal direction. do.

Since the material and construction method of the lightweight material block 30 are already known techniques, further detailed description will be omitted here for the sake of simplification of the specification.

In addition, as shown in FIG. 9 , the vertical reinforcing bar 40 is embedded in the central part 11 of the precast concrete block 10 for slabs 10 in the longitudinal direction to be positioned between the lightweight material blocks 30 .

The vertical reinforcing bar 40 is embedded in the central part 11 of the precast concrete block 10 for a slab, particularly along the longitudinal direction of the rib 113, so that the in-plane horizontal shear resistance of the precast concrete block 10 for the slab and It serves to increase the vertical shear resistance.

The lattice muscle inserted and installed in the conventional H/S is composed of a truss type, and the upper and lower muscles are arranged on the upper and lower sides to extend along the longitudinal direction of the slab, and the length of the upper and lower ends of the lattice muscle is Because it is limited, there is a limit to the lattice reinforcing bars inserted and installed inside the slab. did

However, the vertical reinforcing bars 40 applied to the disclosed contents are arranged in a zigzag up and down direction along the longitudinal direction of the precast concrete block 10 for slabs in the vertical direction to the aforementioned horizontal connecting muscles 20 .

In addition, the upper end of the vertical reinforcing bar 40 protrudes outward from the upper portion of the central portion 11 of the precast concrete block 10 for slab, and the upper end of the protruding vertical reinforcing bar 40 has in-plane shear resistance and vertical shear resistance. It is formed by bending in a zigzag shape to increase.

In addition, in the vertical reinforcing muscle 40, additional vertical reinforcing bars may be further arranged in the middle and both ends in the longitudinal direction. At this time, it is preferable that the additional vertical reinforcing rods 41 arranged in the center are arranged to cross each other in opposite directions with respect to the vertical reinforcement 40, and the additional vertical reinforcing rods 43 arranged at both ends are to the vertical reinforcement 40. It is preferable to be arranged with an offset at regular intervals to each other.

The vertical reinforcing bar 40 of the above-described shape has the advantage that it can be individually manufactured according to the height of the slab, and accordingly, a separate on-site work such as reinforcing the maize reinforcing bar at the site is unnecessary, thereby reducing the construction cost. There is this.

In addition, a hook portion 45 for lifting and moving the precast concrete block 10 for a slab by a crane may be buried in the left side of the central portion 11 of the precast concrete block 10 for the slab.

In addition, as shown in Figures 6 to 8, the wire mesh 50 in the precast concrete block 10 for the slab may be installed horizontally embedded in the upper portion of the lightweight material block (30).

This wire mesh 50 can be used as a substitute for reinforcing bars in concrete facilities, and is configured to compensate for insufficient tensile strength of concrete. If the slabs are joined by the precast concrete block 10 and the horizontal connector 20 for the slab and the construction is made while pouring the concrete on top, the concrete characteristics may be relatively weak to tensile and bending stress compared to the strong compressive force. There, the wire mesh 50 is installed to reinforce it.

In addition, as shown in FIG. 1, after the PC girder is installed, a plurality of PC slabs are installed. As shown in FIG. 10, according to the conventional method using H/S, the PC girder is disposed in both directions. After that, install a slab between them. Accordingly, there was a large amount of on-site work and the amount of reinforcement was considerable, and it was difficult to reduce the amount of reinforcement in the field, especially since it was made in the form of a form.

However, in the case of the precast concrete block 10 for a slab according to the disclosed contents, as the mutual bonding ability is improved, as shown in FIG. By sequentially arranging cast concrete blocks (not shown) and pouring concrete, the amount of reinforcing bars to be reinforced can be significantly reduced, and thus the amount of on-site work can also be significantly reduced.

Although preferred embodiments of the present invention have been described with reference to the accompanying drawings, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and represent all of the technical spirit of the present invention. Therefore, it should be understood that there may be various equivalents and modifications that can be substituted for them at the time of filing the present application. Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and their All changes or modifications derived from the concept of equivalents should be construed as being included in the scope of the present invention.

10: PC slab
11: central part
111: space part
113: Rib
13: wing
20: horizontal joint muscle
21: purchase part
23: inclined part
25: extension
27: connecting wire mesh
30: lightweight material block
40: vertical reinforcing bar
41, 43: additional vertical reinforcement
45: hook part
50: wire mesh

Claims (10)

Precast concrete blocks for slabs in which wing portions extend to a thickness smaller than that of the central portion on both sides of the central portion extending in the longitudinal direction with a predetermined width;
a horizontal connector installed horizontally in the precast concrete block for the slab;
a lightweight material block inserted and installed along the longitudinal direction in the central portion of the precast concrete block for the slab, a plurality of which are spaced apart from each other at a predetermined interval;
a vertical reinforcing bar installed along the longitudinal direction in the central portion of the precast concrete block for the slab so as to be positioned between the lightweight material blocks; and
Including a wire mesh embedded in the upper part of the lightweight material block in the precast concrete block for the slab in the horizontal direction,
The central portion of the precast concrete block for the slab includes a space portion into which the lightweight material block is inserted, and a rib partitioning the lightweight material block to be spaced apart from each other,
The lightweight material block extends in the same cross-section in the longitudinal direction, and both longitudinal ends of the lightweight material block are tapered toward both longitudinal ends of the space portion,
The horizontal connector is installed horizontally across the central portion and the wing portion of the precast concrete block for the slab,
A connecting wire mesh is embedded and fixed on the wing of the precast concrete block for slab and the wing of the neighboring precast concrete block for slab when pouring concrete,
The vertical reinforcement is arranged in a zigzag up and down direction along the longitudinal direction of the precast concrete block for the slab in the vertical direction to the horizontal connector, and the upper end of the vertical reinforcement is outside from the top of the central part of the precast concrete block for the slab. and the upper end of the vertical reinforcing bar is bent in a zigzag shape to increase in-plane shear resistance and vertical shear resistance,
Additional vertical reinforcing bars are arranged at the center and both ends of the precast concrete block for slab, and the additional vertical reinforcing bars arranged in the center of the precast concrete block for slab are arranged to cross each other in opposite directions with respect to the vertical reinforcing bars, An optimized bidirectional precast concrete block slab, characterized in that the additional vertical reinforcing bars arranged on both end sides of the precast concrete block for a slab are offset at regular intervals with respect to the vertical reinforcing bars. delete delete delete delete delete delete delete delete delete

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