KR20170128054A - Precast Concrete(PC) slab for structure and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a precast concrete (PC) slab for a structure and a manufacturing method thereof, wherein the PC slab for a structure comprises: a base plate; and a plurality of ribs formed to protrude from an upper surface of the base plate to improve a coupling force with topping concrete deposited in a site, and spaced at a predetermined distance along a width direction of the base plate. The ribs comprises: a lower surface formed on the upper surface of the base plate; an upper surface spaced at a predetermined height in an upper side direction of the lower surface; and a front surface, a rear surface, and side surfaces connecting the lower surface and the upper surface. Moreover, a length in a width direction is formed to be shorter from the lower surface to upper surface.

Description

TECHNICAL FIELD The present invention relates to a PC slab for a structure and a manufacturing method thereof,

The present invention relates to a PC slab for a structure and a method of manufacturing the same, and more particularly, to a PC slab for a structure having a vertical, horizontal shear performance and adhesion performance, And a method for producing the same.

Generally, when a public building such as a warehouse structure or an underground parking lot having a high height is required, a large load is required. Therefore, a PC member is manufactured and assembled in the field. Such a construction method is usually performed by a PRC (Precast Reinforced Concrete Layer Construction Method) composite method using a half slab (Half PC Slab).

In other words, this PRC composite method is a method of converting a reinforced concrete (Rahmen) structure into a PC (Precast Concrete) and transporting PC materials such as PC columns, PC beams, and half slabs After that, the overburden concrete is placed on the joints of the members and the upper part of the half slab to integrate them in the field. On the other hand, when constructing a building structure such as a warehouse structure or an underground parking lot, a long span is required.

On the other hand, the HCS method is a prestressed structure that improves the tensile resistance performance by applying a compressive force to concrete by using a PS wire with a prestress as a weakness of tensile resistance which is a weak point of concrete It is mainly applied to the ground layer structure by forming a long span of more than 10m by using a hollow slab that reduces the weight of the structure by forming hollow in the concrete section.

However, HCS requires a high-priced equipment for securing the minimum thickness due to the tensile strength of the PS steel wire and the manufacturing of the HCS member, resulting in an increase in the unit price, and it is difficult to repair the member when cracks occur.

Accordingly, a double-slab method has recently been implemented. This is called DTS method. In the double slab, deep reinforcing ribs are provided on the bottom plate, strands are inserted into the lower portion of the reinforcing ribs, and tensile force is applied to the reinforcing ribs to form a single member. The center portion of the double-slab is slightly elevated, and thus it is mainly applied to the ground-layered structure with a long span of about 10 m or more.

However, the double-slab method is difficult to achieve a continuous slab shape (both ends information) because it is seated only in the shape of a simple beam when the PC is straddled, which causes a problem in that the structure becomes weak due to a decrease in resistance against vertical forces such as bending and shearing force In order to improve this, the reinforcing rib is additionally provided or the height of the protruding rib is increased. As a result, manufacturing costs such as the use of a large number of PC columns are increased, leading to a problem of lowering the economical efficiency. In addition, the slabs of MTS, JRS and the like, which are similar to other similar construction methods pointed out in the double tee slab method, also have the same problem.

On the other hand, in the case of a slab having a rib-like rib and a flat bottom surface, it is advantageous in securing a stratification as compared with a slab in which a support rib is exposed downward as in a double Ti slab. And ceiling painting (painting), fireproofing work, etc., it is possible to reduce the construction cost due to the ease of construction of the worker at the time of finishing work, and it is possible to improve the sense of space and beauty by providing a flat surface after construction, There is a growing demand for the development of flat slabs.

Korean Patent Publication No. 10-2013-0028048

It is an object of the present invention to provide a PC slab for a structure and a method of manufacturing the same, which are pre-manufactured in a factory so as to enable quick construction compared to a site installation, and have enhanced vertical and horizontal shearing performance and adhesion performance.

The present invention provides a base plate comprising: a base plate; And a plurality of ribs protruding from an upper surface of the base plate and spaced apart from each other by a predetermined distance along a width direction of the base plate so as to improve a coupling force between the base plate and the topping concrete, A lower surface formed on the upper surface, an upper surface spaced upward from the lower surface by a predetermined height, and a front surface, a rear surface and side surfaces connecting the lower surface and the upper surface, Is formed to be short.

According to another aspect of the present invention, there is provided a method of manufacturing a base plate, comprising: providing a base mold for manufacturing a base plate; Installing a shear connection member inside the base mold such that the shear connection member is spaced apart from the base mold along a width direction of the base mold; Forming a base plate by placing a primary concrete so that a part of the shear connecting member is embedded; Wherein a plurality of rib molds are spaced along a width direction of the base plate on a top surface of the base plate and spaced apart from each other by a bottom surface of the rib mold adjacent to the front end connecting member, So as to form a plurality of ribs integral with the base plate by placing a secondary concrete between the neighboring rib molds so that a part of the shear connecting member is embedded, Each of the ribs formed in the step of forming the plurality of ribs includes a lower surface formed on an upper surface of the base plate, a lower surface spaced upward from the lower surface by a predetermined height, A front surface, a rear surface and side surfaces, And a length in a width direction of the slab is shorter than a width of the slab.

The PC slab for a structure and the manufacturing method thereof according to the present invention have the following effects.

First, since the left side surface and the right side surface of the ribs are formed as inclined surfaces so that the longitudinal section parallel to the width direction of the rib is formed in a trapezoidal shape, when the ribs are manufactured using the rib mold, the rib molds can be easily separated There is an advantage.

Secondly, when forming the ribs, it is possible to simultaneously form the vertical and horizontal shearing stress applied to the ribs on the side surfaces of the ribs, and to produce a slab of higher quality than when forming the shearing stress resistance portion separately The manufacturing time can also be reduced.

Third, since the shear stress resistance portion is formed on the ribs, it is possible to effectively resist the horizontal shear stress and the vertical shear stress between the ribs and the topping concrete even if the shear connecting members are not provided for the entire length of the ribs. You can also save money by reducing costs.

1 is a perspective view illustrating a PC slab for a structure according to an embodiment of the present invention.
2 and 3 are a front view and a plan view of the PC slab for the structure shown in FIG.
Fig. 4 is a side view of the shear connection member shown in Fig. 1. Fig.
5 is a perspective view illustrating a PC slab for a structure according to another embodiment of the present invention.
6 is a perspective view illustrating a PC slab for a structure according to another embodiment of the present invention.
7 is a perspective view illustrating a PC slab for a structure according to another embodiment of the present invention.
8 is a perspective view illustrating a PC slab for a structure according to another embodiment of the present invention.
FIG. 9 is a perspective view illustrating an example in which an underground parking lot is constructed using the PC slabs for a structure according to FIGS. 1 and 6. FIG.
10 is a partial cross-sectional view showing an example of construction using the PC slabs for the structure according to FIG.
11 to 19 show a process of manufacturing a PC slab for a structure according to the present invention.

1 to 19 show a PC slab for a structure and a method of manufacturing the same according to the present invention.

Hereinafter, a PC slab for a structure according to the present invention will be described with reference to FIGS. 1 to 4. FIG. FIG. 1 illustrates a PC slab 1000 for a structure according to an embodiment of the present invention. The PC slab 1000 for a structure according to an embodiment of the present invention includes a base plate 100, a plurality of ribs 300, and a shear connection member 500.

First, the base plate 100 includes a first lower surface (unrepresented), a first upper surface 110 spaced upward from the first lower surface (unrepresented) by a predetermined height, (Not shown) and a first side (unrepresented) 130 connecting the first upper surface 110 and the second upper surface 120. The first front surface 120, According to these configurations, in this embodiment, as shown in FIG. 1, the base plate 100 is formed in the form of a rectangular parallelepiped. Meanwhile, the length of the base plate 100 from the first front surface 120 to the first rear surface (unrepresented) can be variously adjusted.

As described later, the ribs 300 are formed on the first upper surface 110 of the base plate 100. The ribs 300 are formed on the first upper surface 110 between the adjacent ribs 300, 1 grooves 150 are formed. The first grooves 150 improve the bonding force between the PC slab 1000 for the structure and the topping concrete T / C when the topping concrete T / C is laid on the PC slab 1000 for the structure So as to increase the contact area as much as possible. The first grooves 150 are recessed from the first upper surface 110 of the base plate 100 toward the first lower surface and are elongated along the longitudinal direction of the base plate 100 A plurality of spaced-apart base plates 100 are formed along the width direction of the base plate 100.

By forming the plurality of first grooves 150, the first top surface 110 of the base plate 100 is finished with a rough surface to increase the contact area with the topping concrete (T / C) You can.

The ribs 300 are formed on the base plate 100 so as to improve the coupling strength with the topping concrete T / C placed on the PC slabs 1000 in the field, And is spaced apart from the first upper surface 110 of the base plate 100 by a preset distance.

The ribs 300 may include a second upper surface 310 spaced apart from the second lower surface of the first upper surface 110 by a predetermined height in the upward direction, A second front surface 320 connecting the second top surface 310, a second rear surface (not shown), and a second side surface 330. At this time, the length in the width direction from the second lower surface (unrepresented) toward the second upper surface 310 is shorter. The longitudinal length of the ribs 300 is gradually reduced from the second bottom surface to the second top surface 310 to form a trapezoidal longitudinal section parallel to the width direction of the ribs 300.

On the other hand, the second side surface 330 of the rib 300 is formed with a shearing stress resistance part 350 to resist the vertical shearing stress and the horizontal shearing stress applied to the rib 300. The rib 300 includes a second left sloping surface 330 and a second right sloping surface 335. The shear stress resistance portion 350 is formed on each of the second left sloping surface 330 and the second right sloping surface 335. 1, the shear stress resistance part 350 according to the present embodiment includes a plurality of shear keys 350 spaced along a longitudinal direction of the rib 300 and recessed by a predetermined depth, Lt; / RTI >

More specifically, it is formed from the second upper surface 310 to the set position along the oblique direction of the second side surfaces 330 and 335, and the polygonal side surface of the second side surfaces 33 and 335 . In the present embodiment, as shown in FIG. 1, the cross section is formed into a rectangular groove shape.

By forming the shear stress resistance portion 350 on the second side surfaces 330 and 335 of the rib 300 as described above, the horizontal shear stress imposed on the shear connection member 500, which will be described later, (350). Therefore, the fatigue resistance against the horizontal shear stress in the PC slab 1000 for the structure can be prevented from being concentrated to the local site.

In addition, by forming the shear stress resistance portion 350, the shear connection member 500 described later may not be provided along the length of the rib 300, as much as the length of the rib 300. 1, even if the shear connection member 500 is installed only in the remaining portion except for the longitudinal center region of the rib 300, the shear stress resistance portion 350 and the PC slab for the structure 1000) and the horizontal shear stress applied to the substrate.

Accordingly, it is possible to construct the building using the PC slab for building structure 1000, especially when the construction structure having a high height is constructed. In addition, since the weight of the shear connection member 500 is reduced as the shear connection member 500 is omitted, it is possible to manufacture an economical slab that is light in weight and low in manufacturing cost.

The shear connection member 500 is installed to resist a horizontal shear stress and a vertical shear stress between the rib 300 and the topping concrete T / C. Also, the coupling force between the rib 300 and the topping concrete T / C can be improved. A portion of the shear connection member 500 protrudes to the upper side of the rib 300 and the remaining portion is installed to be embedded in the rib 300.

4, the shear connection member 500 includes a plurality of vertical reinforcing bars 510, an upper side of one vertical reinforcing bar 510 and a lower adjacent vertical reinforcing bar 510 The upper bent portions 530 connecting the upper side of one vertical reinforcing bar 510 and the upper side of one of the inclined roots 520 and the upper bent portions 530 connecting the lower side of one of the inclined roots 520 And a lower bending portion 540 connecting the lower side of the adjacent one of the vertical reinforcing bars 510. With this configuration, the shear connecting member 500 is formed in a continuous 'N' shape.

1, the shear connection member 500 may include a portion of the vertical reinforcing bar 510 connected to the upper bent portion 530 and a portion of the inclined roots 520, 300, and the remaining portion is embedded in the inside of the rib 300.

As described above, the shear connection member 500 is installed along the longitudinal direction of the rib 300 in a region other than the set central region. At this time, the 'N' shape of the front end connecting member 500 installed on the front side of the setting central region with respect to the setting central region and the 'N' shape of the front end connecting member 500 installed on the rear side of the setting central region The 'N' shapes are arranged to be symmetrical to each other. In the present embodiment, when the length of the rib 300 is divided into three equal parts, the front end connecting member 500 is not provided in the center 1/3 region, And the front end connecting member 500 is installed in the rear side 1/3 region.

In the present embodiment, as shown in FIG. 1, the front end connecting member 500 is installed on the front side and the rear side with two shear connection members 500 superimposed on the set center region. That is, the other shear connection member 500 overlapping the one shear connection member 500 is moved forward or backward by a half pitch of the pitch between adjacent vertical reinforcing bars 510 Respectively. However, since the present invention is limited only to the present embodiment, it can be arranged so as to overlap in various forms. The number of the shear connection members 500 installed on the ribs 300 may be variously changed according to the vertical shear stress and the horizontal shear stress to which the PC slab 1000 is to be resisted.

Fig. 5 shows another embodiment of the PC slab for the structure shown in Fig. As shown in FIG. 5, the PC slab 1000 'for the structure includes a first upper surface 110 of the base plate 100 between the ribs 300, The first grooves for increasing the area may be omitted.

Meanwhile, FIG. 6 shows another embodiment of the PC slab for the structure shown in FIG. As shown in Fig. 6, the PC slab 1000 " for the structure has a shear connection member omitted. For example, in the case of constructing the underground parking lot with the PC slabs for the structure according to the present invention, since the passage of medium vehicles is less than that of the underground two stories, The PC slab 1000 " for the structure may be applied.

Figs. 7 and 8 show another embodiment of the PC slab for the structure according to the present invention. As shown in FIGS. 7 and 8, the PC slabs 1000a and 1000b for the structure according to still another embodiment are different from the PC slab 1000 for the structure shown in FIG. 1 in the ribs 300 Only the shear stress resistance parts 350a and 350b formed are different. Therefore, in FIGS. 7 and 8, the same reference numerals are assigned to the same components as those in FIG. 1, and a description thereof will be omitted.

Referring to FIG. 7, the shear stress resistance portion 350a of the PC slab 1000a according to another embodiment of the present invention is positioned at a sloping center region of the second side surfaces 330 and 335 And a plurality of shear keys 350a spaced along the longitudinal direction and spaced from the second side surfaces 330 and 335 by a predetermined depth and having a polygonal cross section in parallel with the second side surfaces 330 and 335, . The shear key 350a in the present embodiment is formed in a groove shape having a rectangular cross section having a long length along the longitudinal direction of the rib 300 as shown in FIG.

8, the shear stress resistance part 350b of the PC slab 1000b according to another embodiment of the present invention is elongated along the longitudinal direction of the rib 300, And a plurality of second grooves 350b spaced along the slanting direction of the second side surfaces 33 and 335 by a predetermined interval.

FIG. 9 shows an example in which an underground parking lot is constructed using the PC slabs for structures according to FIGS. 1 and 6. FIG. 10 shows an example of a construction using the PC slab 1000 for the structure shown in FIG. Is shown. First, as shown in Fig. 9, an underground parking lot is installed together with PC columns 2, PC beams 3, and PC slabs 1000, 1000 " for the structure.

The PC slab 1000, 1000 " for the structure is seated on the PC beams 3. In the construction of the underground parking lot, the PC slabs 1000 for the structure as shown in Fig. 1 are seated on the PC beams 3 to form the floor of the first basement. On the other hand, the PC slabs 1000 " for the structure as shown in Fig. 6 are seated on the PC beams 3 to form the floor of the basement 2 floor.

This is because, in the case of an underground parking lot as described above, the PC slab 1000 for the structure provided with the shear connecting member 500 is used so as to withstand a load more strongly because a heavy vehicle enters the first floor . On the other hand, since the entrance of the heavy vehicle is limited to the under two stories, the PC slab (1000 ") for the structure without the shear connection member is used.

Referring to FIG. 10, the PC slab 1000 for the structure is continuously disposed on the PC beam 3 along the width direction. In the widthwise both side surfaces of the base plate 100 of the PC slab 1000 for the structure, that is, the first left side (unrepresented) and the first right side surface 130, chamfered portions, which are connected to the first top surface 110, .

As shown in FIG. 10, when the PC slabs 1000 for the structure are continuously disposed along the width direction, the first slabs 1000 adjacent to the first right side surface 130 of the one PC slab 1000 The first left side (unrepresented) of the PC slab 1000 for the structure is brought into close contact with each other and brought into surface contact with each other. At this time, the waterproof filler can be injected into the space formed by the chamfer between the first right side surface 130 and the first left side surface (not shown). As the waterproof filler, mortar, urethane foam or styrofoam is used.

Particularly, when the mortar is injected, the PC slabs 1000 for the structure are continuously disposed to adhere the PC slabs 1000 for the structure before the topping concrete T / C is installed. Also, when the topping concrete (T / C) is laid, it is possible to prevent the topping concrete (T / C) from flowing out between adjacent PC slabs (1000).

9 and 10, when the building structure is constructed using the PC slabs for the structure, the plurality of first grooves 150 formed on the first upper surface 110 are formed, It is possible to have an effect of improving the bonding force with concrete (T / C). The shear connection member 500 provided on the rib 300 and the shear stress resistance portion 350 formed on the second side surfaces 330 and 335 of the rib 300 The resistance against the vertical shear stress and the horizontal shear stress between the PC slab 1000 and the topping concrete (T / C) is improved, so that it is possible to construct a more secure construction structure.

By using the PC slab for a structure according to the present invention, it is possible to construct a structure which requires a lot of loads, such as an underground parking lot and a high-rise building structure (refrigeration, warehouse) Particularly, since the bottom surface of the PC slab for a structure is flat, it is advantageous in securing the flooring compared with the conventional double-tee type PC slab, and the ceiling can provide an effective space expansion and an excellent opening feeling. By forming the shear keys on the ribs, the horizontal and vertical shear stress acting on the PC slabs for the structures and the adhesion with the topping concrete are strengthened, thereby reducing the use of the shear connection members reinforced on the PC slabs can do.

Hereinafter, a method of manufacturing a PC slab for a structure according to the present invention will be described with reference to FIGS. Referring to FIG. 11, a base mold 10 is first installed to manufacture the base plate 100. The base mold 10 includes a bottom surface 11 and a front surface 12, a rear surface 13 and side surfaces 14 and 15 extending upward from the bottom surface 11. The base mold 10 has an open top surface, and the primary concrete is poured through the top surface (unrepresented).

When the base mold 10 is installed, the front end connecting member 500 is installed in the base mold 10 as shown in FIG. A wire mesh 21 for improving rigidity while forming a skeleton of the base plate 100 in the base mold 10 before the shear connection member 500 is installed, I will.

The wire mesh 21 is disposed inside the base mold 10 while being spaced apart from the base mold 10 by a predetermined distance along the longitudinal direction and the width direction. Since the steel material 23 reinforces the rigidity of the ribs 300 formed on the base plate 100, the ribs 300 correspond to the positions of the ribs 300 to be formed on the base plate 100 As shown in FIG.

After the wire mesh 21 and the steel material 23 are laid, the front end connection member 500 is installed at a position corresponding to the position where the rib 300 is to be formed, First concrete is poured. At this time, the wire mesh 21 and the steel material 23 are completely embedded in the primary concrete to be laid, and a part of the shear connection member 500 is embedded in the laid primary concrete.

As described above, when the primary concrete is poured into the base mold 10, a plurality of first grooves 150 are formed on the upper surface 110 of the base plate 100 before the primary concrete is hardened .

As a method of forming the plurality of first grooves 150, the plurality of first grooves 150 are formed by using the mold block 20 as shown in FIG. The mold block 20 includes a bottom surface 21 and a top surface 22 spaced apart from the bottom surface 21 by a predetermined height and a side surface (unrepresented) connecting the bottom surface 21 and the top surface 22, As shown in FIG. The first concave and convex portions 21a corresponding to the first concave grooves 150 are formed on the lower surface 21. The protrusions 21a are formed on the lower surface 21 of the mold block 20 so as to extend along the longitudinal direction of the mold block 20 and spaced along the width direction of the mold block 20 .

13, before the primary concrete forming the base plate 100 is cured, the mold block 20 is disposed on the first upper surface 110 of the base plate 100, The primary concrete is pressed. When the primary concrete is cured in such a state that the lower surface 21 of the mold block 20 on which the projections and depressions 21a are formed is directed to the primary concrete forming the base plate 100 and pressed, The first grooves 150 are formed.

The plurality of ribs 300 are formed on the first upper surface 110 of the base plate 100 when the base plate 100 having the first grooves 150 formed therein is formed by the above-described method. The plurality of ribs 300 may be formed on the base plate 100 such that a plurality of rib molds are spaced at predetermined intervals along the width direction of the base plate 100, And a secondary concrete is cast in the spacing space between the rib molds.

More specifically, the rib molds are symmetrically disposed such that the gap between the lower surfaces of the neighboring rib molds relative to the front end connecting member 500 is longer than the gap between the upper surfaces of the rib molds. As described above, the rib 300 formed by the rib molds has a shorter width in the width direction from the second lower surface (unrepresented) to the second upper surface 310. The length in the width direction is gradually reduced toward the second upper surface 310 from the second lower surface (unrepresented), so that the vertical side surface of the rib 300 is formed in a trapezoid shape parallel to the width direction.

When forming the ribs 300, the second side surfaces 330 and 335 of the ribs 300 may be provided with shear stress resistance portions 350 (not shown) which resist vertical and horizontal shearing stresses applied to the ribs 300 Are simultaneously formed.

Referring to FIGS. 14 and 15, the rib molds 30 and 30 'forming the rib 300 according to an embodiment of the present invention are arranged such that the rib molds extend in the width direction of the base plate 100 And a second rib bold 30 'disposed in a widthwise set edge region of the base plate 300. The first rib molds 30'

The first rib bold 30 includes a lower surface 31 and an upper surface 32 spaced apart from the lower surface 31 by a predetermined height and side surfaces 33 and 34 connecting the lower surface 31 and the upper surface 32. [ ). ≪ / RTI > The longitudinal length of the first rib mold 30 gradually increases from the bottom surface 31 toward the top surface 32 so that the vertical longitudinal side of the first rib mold 30 is inversely trapezoidal And the side surfaces (33, 34) are formed as inclined surfaces.

Likewise, the second rib mold 30 'has an inverted trapezoidal longitudinal section parallel to the width direction of the rib mold 30' as in the case of the first rib mold 30, while the second rib mold 30 ' Only one of the side surfaces 33 is formed as an inclined surface.

The first rib molds 30 and the second rib molds 30 are spaced apart from each other along the width direction of the base plate 100 on the first upper surface 110 of the base plate 100 The inclined surfaces 33 and 34 are disposed symmetrically with respect to the shear connection member 500. Accordingly, the ribs 300 are also formed in a trapezoidal shape in longitudinal section parallel to the width direction.

The protrusion 35 is formed on the first rib mold 30 and the second rib mold 30 so that the shear stress resistance portion 350 is formed at the same time when the rib 300 is formed . More specifically, protrusions 35 are formed on the inclined surfaces 33 and 34 of the first rib mold 30 and the inclined surfaces 33 of the second rib mold 30 '. The protrusions 35 extend from the upper surface 32 to the predetermined positions along the inclined surfaces of the inclined surfaces 33 and 34 and protrude from the inclined surfaces 33 and 34 and extend in parallel to the inclined surfaces 33 and 34 Are formed in a polygonal shape. In this embodiment, the cross section is formed as a projection 35 having a rectangular shape.

When the ribs 300 are formed by the projections 35 formed on the inclined surfaces 33 and 34 of the first rib mold 30 and the inclined surfaces 33 of the second rib mold 30 ' The shear stress resistance portion 350 applied to the protrusion 35 corresponding to the groove-shaped shear key 350 is simultaneously formed on the left inclined face 330 and the right inclined face 335 of the rib 300. [

FIG. 16 shows a process of forming the rib 300 in the PC slab 1000a for a structure according to another embodiment of the present invention shown in FIG. As shown in FIG. 16, the ribs 300 of the PC slab 1000a for the structure are also formed by the first rib mold 30a and the second rib mold 30a '. However, the protrusion 35a for forming the shear stress resistance portion 350a of the rib 300 is different from that of FIG.

In the present embodiment, the projections 35a are protruded from the inclined surfaces 33 and 34 in the central region of the inclined surfaces 33 and 34 in the inclined direction. At this time, a plurality of sections are formed in a polygonal shape in parallel with the slopes 33, 34 and spaced apart from each other by a predetermined interval along the longitudinal direction of the slopes 33, 34. In the present embodiment, the protrusion 35a has a rectangular sectional shape having a long length along the longitudinal direction of the first rib mold 30a and the second rib mold 30a '. The rib 300 is formed by the first rib mold 30a and the second rib mold 30a and is applied to a groove-shaped shear key 350 'corresponding to the projection 35a The shear stress resistance portion 350a is formed at the same time.

17 shows a process of forming the rib 300 of the PC slab 1000b for a structure according to another embodiment of the present invention shown in FIG. As shown in FIG. 17, ribs 300 of the PC slab 1000b for the structure are also formed by the first rib mold 30b and the second rib mold 30b '.

Second concavities and convexities 35b are formed in the first rib mold 30b and the second rib mold 30b` according to the present embodiment to form the shear stress resistance portion 350b of the rib 300 . More specifically, the second irregularities 35b are formed on the inclined surfaces 33 and 34 of the first rib mold 30b and the inclined surfaces 33 of the second rib mold 30b '.

The second concave and convex portions 35b are formed on the inclined surfaces 33 and 34 of the first rib mold 30b and the inclined surfaces 33 of the second rib mold 30b ' Is formed to extend from the inclined surfaces 33 and 34 of the first rib mold 30b and the inclined surfaces 33 of the second rib mold 30b ' do. The second concave and convex portions 35b are spaced at predetermined intervals along the oblique directions of the inclined surfaces 33 and 34 of the first rib mold 30b and the inclined surfaces 33 of the second rib mold 30b ' .

The ribs 300 are formed by the first rib mold 30b and the second rib mold 30b` formed with the second concavities 35b and the second concavities 35b and the second concave- The shearing stress resistance portion 350b applied to the corresponding second grooves 350b is formed at the same time.

18 and 19 illustrate another embodiment of the rib molds 30c forming the ribs 300 according to an embodiment of the present invention and the rib molds 30c using the rib molds 30c, Is formed. As shown in FIGS. 18 and 19, only one side 33c of the rib mold 30c according to the present embodiment is formed as an inclined surface, and the shear stress resistance portion 350 is formed on the inclined surface 33c A protrusion 35c that can be formed is formed. When the rib molds 30c are disposed on the base plate 100, the inclined surfaces 33c are disposed symmetrically with respect to the front end connecting member 350. [

18, the center of the base plate 100 in the width direction, that is, the rib molds 30c disposed between the front end connection members 500, do. Accordingly, in the present embodiment, the first grooves 150 are formed between the adjacent ribs 300, that is, the upper surface of the base plate 100, while the ribs 300 are formed using the rib molds 30c do.

In order to form the first grooves 150 in this embodiment, the rib molds 30c are disposed on the base plate 100 before the primary concrete is cured as described above, The upper surface 110 of the base plate 100 is scraped off by using the scraping member 1 between the adjacent rib molds 30c disposed between the connecting members 500. [ The scraping member 1 has a plurality of hooks 1a spaced apart from each other at a predetermined interval. When the upper surface 110 of the base plate 100 is scratched while moving the scraping member 1 along the longitudinal direction of the base plate 100, The plurality of first grooves 150 recessed in the direction toward the lower surface (unrepresented) are formed.

Since the PC slab for a structure manufactured through the above-described manufacturing process forms trapezoidal ribs using reverse-trapezoidal rib molds whose sides are formed as inclined surfaces, the rib molds are formed between the ribs formed by curing the concrete There is an advantage that it can be easily separated.

If the rib is formed in a rectangular shape in its longitudinal section, it is not easy to separate the rib mold from the rib. Particularly, when forming the shear stress resistance portion at the same time as the rib, the rib is caught by the second irregularities or protrusions for forming the shear stress resistance portion, so that it becomes more difficult to separate the rib mold. This may cause the quality of the PC slab for the structure to be deteriorated by the impact caused by the collision between the rib mold and the rib in the process of separating the rib mold from the PC slab for the structure.

However, according to the present invention, it is possible to separate the rib mold without applying a large force or impact by the trapezoidal shape and the reverse trapezoidal shape, thereby preventing the rib from being damaged during the process of separating the rib mold. Thus, the quality of the PC slab for a structure is improved.

Further, the rib and the shear stress resistance portion can be simultaneously formed only by the concrete pouring, and there is an advantage that a high-quality PC slab for a structure can be manufactured without lowering the rigidity of the rib.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1000, 1000` 1000a, 1000b: PC slab for structure
100: base plate 150: first groove
300: ribs 350, 350a, 350b: shear stress resistance part
500: Shear connection member 1: Scratch member
10: base mold 20: mold block
21a: 1st unevenness
30, 30a, 30b: first rib mold 30`, 30a`, 30b`:
35; Second unevenness 35a, 35b:

Claims (2)

A base plate; And
And a plurality of ribs protruding from the upper surface of the base plate so as to improve bonding force with the topping concrete placed at the site, the ribs spaced apart from each other by a predetermined interval along the width direction of the base plate,
The ribs
A bottom surface formed on an upper surface of the base plate, a top surface spaced apart from the bottom surface by a predetermined height, and front, rear and side surfaces connecting the bottom surface and the top surface,
And a length in the width direction is formed shorter toward the upper surface from the lower surface. Providing a base mold for making a base plate;
Installing a shear connection member inside the base mold such that the shear connection member is spaced apart from the base mold along a width direction of the base mold;
Forming a base plate by placing a primary concrete so that a part of the shear connecting member is embedded;
Wherein a plurality of rib molds are spaced along a width direction of the base plate on a top surface of the base plate and spaced apart from each other by a bottom surface of the rib mold adjacent to the front end connecting member, So as to form a plurality of ribs integral with the base plate by placing secondary concrete between the neighboring rib molds so that a part of the shear connecting member is embedded, ,
Each of the ribs formed in the step of forming the plurality of ribs,
A lower surface formed on an upper surface of the base plate; a lower surface spaced apart from the lower surface by a predetermined height; a front surface, a rear surface and side surfaces connecting the lower surface and the upper surface; Wherein the length of the slab is shorter than the length of the slab.

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