KR101781823B1 - Concrete slab and concrete slab manufacturing method and method for manufacturing a concrete constructure provided the same - Google Patents

Abstract

The present invention relates to a concrete slab, a method of manufacturing the concrete slab, and a method of constructing a concrete structure with a concrete slab, the method comprising the steps of: constructing first and second walls protruding vertically from the upper surface; The method comprising: fabricating a concrete slab having a plurality of horizontally connected steel members protruding from both sides thereof; Connecting one of the horizontal connecting steels of the concrete slab to the vertical connecting steels of the first wall and connecting the other one of the horizontal connecting steels of the concrete slab to the vertical connecting steels of the second wall; And an upper surface of the first wall and one side surface of the concrete slab are connected by concrete so as to enclose the vertical connecting steels of the first wall and one of the horizontal connecting steels of the concrete slab and the vertical connecting steels of the second wall and the concrete And connecting the upper surface of the second wall and the other side of the concrete slab to the concrete so as to enclose the other horizontal connecting steels of the slab. According to the present invention, the construction is simple and the construction period is shortened.

Description

TECHNICAL FIELD [0001] The present invention relates to a concrete slab, a method of manufacturing the concrete slab, a concrete slab, a method of manufacturing the concrete slab, and a method of constructing a concrete structure including the concrete slab.

The present invention relates to a concrete slab, a method of manufacturing the concrete slab, and a method of constructing a concrete structure including a concrete slab.

Generally, a ramen bridge is composed of walls supported at each side of the road at regular intervals, a pier located between the walls, and an upper plate connecting the upper part of the walls and the upper part of the pier, Is made up of one structure, i.e., one body. Another form of ramen bridge consists of two walls and a roof without a bridge in the above configuration.

As a method of constructing one of these concrete structures, there is a method of installing a bridge in accordance with the shape of a bridge, placing the concrete in a form to integrally construct the bridge, installing a wall (or a bridge) in advance A method of constructing a bridge by installing a concrete in an upper part of a wall and placing a concrete in a formwork and a plurality of precast slabs (also called a top plate) are mounted on the upper part of a wall (or a pier) Are integrally bonded to each other.

Korean Patent Publication No. 2005-0055171 (published on June 13, 2005) (hereinafter, referred to as " Preceding Technology 1 "), Korean Patent Publication No. 2012-0065218 Technology 2), a method of constructing a ramen bridge is disclosed.

In the prior art 1, girders including a plurality of eye-shaped beams are horizontally arranged on the upper surface of the walls so as to connect the walls to the walls, and then the girders and the walls are connected to each other by a connecting device. Put it in place. However, in the prior art 1, since a plurality of girders are installed on the upper surface of a wall and a wall, a mold is installed to surround the girders, and then the concrete is cured. There is a problem that takes a long time.

In the prior art 2, the connecting steels are installed horizontally on the upper surfaces of the two walls, the both ends of the girders including the eye sections are connected to the connecting steel members of the two walls, and the molds are installed to surround the girders. Put it in place. However, in the prior art 2, since the concrete is cured after installing the formwork to enclose the girders, there are many work operations and the girders must be covered with concrete, which complicates the operation and takes a long time.

It is an object of the present invention to provide a concrete slab which is simple in construction and shortens a construction period, a method of manufacturing the concrete slab, and a method of constructing a concrete structure with a concrete slab.

In order to achieve the object of the present invention as described above, a first unit concrete slab having a plurality of first horizontal connecting steels protruded from a side surface thereof; A second unit concrete slab having a plurality of second horizontal connecting steels protruding from a side surface thereof; Connecting means for connecting the first horizontal connecting steels and the second horizontal connecting steels; And a connecting concrete part for connecting the first and second unit concrete slabs while surrounding the first and second connecting steel materials.

Preferably, each of the first and second unit concrete slabs facing each other is provided with a blocking protrusion at the bottom of each side thereof to be in contact with each other.

Also, the present invention provides a method of manufacturing a unit concrete slab, comprising: preparing first and second unit concrete slabs each having a plurality of horizontally connected steel members on a side surface thereof; Connecting the horizontal connected steels of the first unit concrete slab and the horizontal connected steels of the second unit concrete slab to each other; And connecting the first and second unit concrete slabs to concrete so as to surround the horizontal connection steel members of the first and second unit concrete slabs.

In addition, the method may further include: constructing the first and second walls protruding from the vertically connected steel plates, respectively; The method comprising: fabricating a concrete slab having a plurality of horizontally connected steel members protruding from both sides thereof; Connecting one of the horizontal connecting steels of the concrete slab to the vertical connecting steels of the first wall and connecting the other one of the horizontal connecting steels of the concrete slab to the vertical connecting steels of the second wall; And an upper surface of the first wall and one side surface of the concrete slab are connected by concrete so as to enclose the vertical connecting steels of the first wall and one of the horizontal connecting steels of the concrete slab and the vertical connecting steels of the second wall and the concrete And connecting the upper surface of the second wall and the other side of the concrete slab to concrete by wrapping the other of the horizontal connection steels of the slab with concrete.

The concrete slab includes a first unit concrete slab having a plurality of first horizontal connecting steels protruded on both sides thereof; A second unit concrete slab in which a plurality of second horizontal connecting steels protrude from both sides; Connecting means for connecting the first and second horizontal connecting steels of the first and second unit concrete slabs; And a connecting concrete part for connecting the first and second unit concrete slabs while covering one of the first and second horizontal connecting steels of the first and second unit concrete slabs.

The concrete slab is preferably formed in the form of a horizontal plate or a curved plate.

Also, there is provided a method of constructing a bridge structure, comprising: constructing first and second walls, Fabricating first and second concrete slabs having a plurality of first horizontal connecting steels on one side and second horizontal connecting steels on the other side, respectively; Connecting the first horizontal connecting steels of the first concrete slab to the vertical connecting steels of the first wall and connecting the second horizontal connecting steels of the first concrete slab to the vertically connecting steels of the pier; Connecting the first horizontal connecting steels of the second concrete slab to the vertical connecting steels of the second wall respectively and connecting the second horizontal connecting steels of the second concrete slab to the vertically connecting steels of the pier; And connecting one side of the first concrete slab and the upper surface of the first wall to concrete so as to enclose the first horizontal slabs of the first concrete slab and the vertical connection steels of the first wall, The upper surface of the second wall and one side of the second concrete slab are connected by concrete so as to enclose the first horizontal connection steel members of the steel and the second concrete slab, and the second horizontal connection steel members of the first concrete slab and the second horizontal connection steel member of the second concrete slab, 2) connecting the second horizontal connecting steels of the concrete slab and the vertical connecting steels of the pier to form a concrete structure.

The first and second concrete slabs may include a first unit concrete slab having a plurality of first horizontal connecting steels protruding from opposite sides thereof, respectively; A second unit concrete slab in which a plurality of second horizontal connecting steels protrude from both sides; Connecting means for connecting the first and second horizontal connecting steels of the first and second unit concrete slabs; And a connecting concrete part for connecting the first and second unit concrete slabs while covering one of the first and second horizontal connecting steels of the first and second unit concrete slabs.

The first and second concrete slabs are preferably formed in the form of a horizontal plate or a curved plate, respectively.

In the present invention, the walls (including a pier in the case of the second embodiment) and the concrete slab (s) are respectively manufactured, and then the concrete slab is lifted to connect the vertically-connected steel members protruding from both sides of the concrete slab, After the connection, the mold is installed in the connection part, the concrete is put in the mold and cured to form the concrete connection part. Therefore, the process of manufacturing the concrete structure with the slab is simple, and the concrete structure with the slab is poured into the concrete and is not cured, but is divided into the walls and the upper plate. The construction period is shortened. In addition, since the structure of the formwork is small and simple, it is easy to install the formwork, and the time to install and dismantle the formwork is shortened.

In addition, the structural strength of the concrete structure is strengthened by the provision of vertical connection steels and horizontal connection steels between the wall and the concrete slab and between the piers and the concrete slab.

Further, since the concrete slab (s) constituting the upper plate of the concrete structure can be manufactured by precast at the installation site or can be manufactured in the factory by precast and can be transported to the installation site, the construction of the concrete slab So that it can be freely manufactured.

In the present invention, when a concrete slab is large, unit concrete slabs are manufactured, and unit concrete slabs are connected to each other to produce a concrete slab. Therefore, the size of the concrete slab can be adjusted according to the size of the rafter bridge plate, Design and construction are free.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flowchart showing a first embodiment of a method of constructing a concrete structure with a concrete slab according to the present invention;
FIGS. 2, 3 and 4 are side views, respectively, showing a first embodiment of a method of constructing a concrete structure with a concrete slab according to the present invention,
FIG. 5 is a side view showing that vertically-connected steels are arranged in two rows in a wall constituting a first embodiment of a method of constructing a concrete structure with a concrete slab according to the present invention;
6 is a side view showing another embodiment of the concrete slab constituting the first embodiment of the method of constructing a concrete structure with a concrete slab according to the present invention,
FIG. 7 is a side view showing that a concrete slab is a curved plate in the first embodiment of the method of constructing a concrete structure with a concrete slab according to the present invention,
8 is a flowchart showing a second embodiment of a method of constructing a concrete structure having a concrete slab according to the present invention.
FIGS. 9, 10 and 11 are side views, step-by-step views, respectively, of a second embodiment of a method of constructing a concrete structure with a concrete slab according to the present invention,
12 is a side view showing that concrete slabs are curved plates in a second embodiment of a method of constructing a concrete structure with a concrete slab according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, concrete slabs according to the present invention, a method of manufacturing the concrete slabs, and a method of constructing a concrete structure including concrete slabs will be described with reference to the accompanying drawings.

1 is a flowchart showing a first embodiment of a method of constructing a concrete structure having a concrete slab according to the present invention. FIGS. 2, 3, 4 and 5 are process drawings showing a first embodiment of a method for constructing a concrete structure with a concrete slab according to the present invention, respectively.

As shown in FIGS. 1, 2, 3, 4 and 5, in the first embodiment of the method for constructing a concrete structure with a concrete slab according to the present invention, a plurality of vertically- The first and second walls 100 and 200 are constructed. The first wall 100 and the second wall 200 are spaced apart from each other. The first and second walls 100 and 200 each have a base 110 and a ground 210 located on the ground, connecting portions 120 and 220 formed on the top of the bases 110 and 210, And a body portion 130 (230) formed on the body 120 (220). A plurality of vertically connected steel materials H are provided on the upper surfaces of the body portions 130 and 230. The first and second walls 100 and 200 having a plurality of vertically connected steel plates H are installed in the same manner.

A method in which the first wall 100 is constructed is as follows. A body portion 130 having a plurality of vertically connected steel plates H is formed on both sides and a base portion 110 having a plurality of vertically connected steel plates H protruding from the upper surface thereof is fabricated on a foundation foundation.

The main body 130 includes a rectangular shaped concrete plate having a predetermined thickness, reinforcing bars laid on the concrete plate, and a plurality of vertical connecting steels H protruding from both sides of the concrete plate. It is preferable that the reinforcing bars each projected on both side surfaces of the concrete plate project. The vertically-connected steel material H may be an eye-shaped steel having an alphabet letter shape (or etched shape) in cross section and may be a diagonal shape steel having a diagonal shape in cross section, and may be a cylindrical pipe having a circular section. That is, the vertically-connected steel material H can be realized in various shapes. The vertically connected steel material H of the body portion 130 is provided on the concrete plate such that it is smaller than the length of the concrete plate of the body portion 130 and protruded on both side surfaces in the longitudinal direction of the concrete plate, The non-protruding portions are filled up to a predetermined distance from the side of the concrete plate. It is preferable that the vertically-connected steel plates H provided on both side surfaces of the concrete plate of the main body 130 are arranged in a line. On the other hand, the connecting steels provided on both side surfaces of the concrete plate may be arranged in two rows as shown in Fig. The connection strength is enhanced when the vertical connection steels (H) are arranged in two rows.

The base portion 110 includes a hexahedral concrete body, reinforcing bars embedded in the concrete body, and vertical connecting steels H protruding from the upper surface of the concrete body. Reinforcing bars 230 protrude from the upper surface of the concrete body 220. It is preferable that the vertical connecting steel material H of the base portion 110 is formed in the same shape as the vertical connecting steel material 110 of the body portion 130. The vertically connected steels H provided on the upper surface of the concrete body 220 are arranged corresponding to the vertically connected steels H on one side of the main body 130.

It is preferable that the foundation 110 is formed by placing the concrete on the foundations and placing the concrete on the concrete after curing. On the other hand, the foundation part 110 can be manufactured in a precast factory and then transported to a foundation foundation. In addition, the body portion 130 can be manufactured in the field, can be manufactured in a factory in a precast, and then transported to the site. The body portion 130 and the base portion 110 can be manufactured at the same time.

The main body 130 is vertically erected so that one vertical connecting steel H of the main body 130 and the vertically connecting steel H of the base 110 are connected to each other. The vertical connecting steel material H of the body portion 130 and the vertically connecting steel material H of the base portion 110 may be connected by a connecting means and the connecting means may be a bolt and a nut. The vertically connected steel members H of the body portion 130 and the vertically connected steel members H of the base portion 110 are connected to each other and then the protruded reinforcing bars of the body portion 130 and the projections of the base portion 110 The reinforced bars are connected to each other by using wires or the like. The plate PL is coupled to the end face of the vertically connecting steel material H of the base 110 and the end face of the vertically connecting steel material H of the body 130 respectively and the two plates PL are connected by the connecting means It is preferable to be connected.

The concrete is placed between the lower surface of the main body part 130 and the upper surface of the base part 110 so that the concrete can be poured therein and the concrete is poured and cured to connect the main body part 130 and the base part 110 . The connection portion 120 connects the body portion 130 and the base portion 110. The side surface of the body portion 130 facing the upper surface of the base portion 110 becomes the lower surface and the opposite side surface becomes the upper surface.

3, after the first and second walls 100 and 200 are constructed as described above, a concrete slab 300 having a plurality of horizontal connection steels B on both sides thereof The manufacturing step is proceeded. The concrete slab 300 can be manufactured simultaneously with the first and second walls 100 and 200.

The first embodiment of the concrete slab 300 includes a concrete plate 310, reinforcing bars (not shown) that are embedded in the concrete plate 310, A plurality of horizontal connecting steels B are provided. The concrete plate 310 has a rectangular plate shape having a length corresponding to the distance between the first wall 100 and the second wall 200 and a width corresponding to the width of the first and second walls 100, . It is preferable that the reinforcing bars each projected on both sides of the concrete plate 310 of the concrete slab are protruded. The horizontally-connected steel material B may be an eye-shaped steel having an eye-shaped section and a diagonal-shaped steel having a diagonal cross-section. That is, the horizontally-connected steel material B can be implemented in various shapes. The horizontal connecting steel material B of the concrete slab 300 is smaller than the length of the concrete slabs 310 of the concrete slabs 300 and is provided on the concrete slabs 310 so as to protrude from both sides of the longitudinal direction of the concrete slabs 300 The non-protruding portion of the horizontally-connected steel material B is buried at a predetermined distance from the side surface of the concrete plate 310. It is preferable that the horizontal connecting steels B provided on both side surfaces of the concrete plate 310 of the concrete slab 300 are arranged in a row. On the other hand, the horizontal connection steels B provided on both sides of the concrete plate 310 of the concrete slab 300 may be arranged in two rows. The connection strength is enhanced when the horizontal connection steels (B) are arranged in two rows.

In a second embodiment of the concrete slab 300, a plurality of unit concrete slabs are connected to each other. The second embodiment of the concrete slab 300 is applicable to a case where the length is long. The second embodiment of the concrete slab includes, as shown in FIG. 6, a first unit concrete slab 320 having a plurality of first horizontal connecting steels B1 protruded on both sides thereof; A second unit concrete slab (330) having a plurality of second horizontal connecting steels (B2) protruded on both sides thereof; Connecting means (not shown) for connecting the first and second horizontal connecting steels B1 and B2 of the first and second unit concrete slabs 320 and 330; The first and second unit concrete slabs 320 and 330 are connected to the first and second unit concrete slabs 320 and 330 while surrounding one of the first and second horizontal connecting steels B1 and B2. (340).

A method of manufacturing the second embodiment of the concrete slab 300 is as follows.

A plurality of unit concrete slabs each having a plurality of horizontal connecting steels on both sides thereof are manufactured. And a plurality of unit concrete slabs are connected to each other. Hereinafter, a case where two unit concrete slabs are connected will be described. The two unit concrete slabs are referred to as a first unit concrete slab 320 and a second unit concrete slab 330. The first and second unit concrete slabs are each composed of a square concrete plate having uniform thicknesses, reinforcing bars laid inside the concrete plate, horizontal connecting steels B1 and B2 protruding from both sides of the concrete plate, . It is preferable that the reinforcing bars projected on the side of the concrete plate where the horizontal connecting steels protrude. Horizontally connected steel members protruding from the first unit concrete slabs 300 are referred to as first horizontal connecting steels B1 and horizontal connecting steels protruding from the second unit concrete slabs 300 are referred to as second horizontal connecting steels B2 do.

After the first and second unit concrete slabs 320 and 330 are manufactured, the first and second unit concrete slabs 320 and 330 are horizontally adjacent to each other and the first unit concrete slab 320 and the first unit concrete slab 320 Connecting the horizontally connected steels B1 and one of the second horizontal connecting steels B2 of the second unit concrete slab 330 to each other. The first and second horizontal connecting steels B1 and B2 are connected by a connecting means, and the connecting means may be a bolt and a nut. After connecting the first and second horizontal connecting steels B1 and B2 to each other, the reinforcing bars protruding from one side of the first and second unit concrete slabs 320 and 330 are connected to each other using a wire. The first and second unit concrete slabs 320 and 330 are connected to each other by the first and second unit concrete slabs 320 and 330 while surrounding the first and second horizontal connecting steels B1 and B2 of the first and second unit concrete slabs 320 and 330 The mold is installed so that concrete can be poured into it. The concrete is poured and cured in the form to form the connecting concrete part 340 connecting the first and second unit concrete slabs 320 and 330.

The second embodiment of the concrete slab is externally the same as the first embodiment. However, in the second embodiment of the concrete slab, the first and second horizontal connecting steels B1 and B2 are connected to each other inside the center portion, and the concrete plates of the first and second unit concrete slabs 300 are connected A connecting concrete part 340 is provided.

The first and second unit concrete slabs 320 and 330 are preferably provided with blocking protrusions F1 and F2 on one side of the first and second unit concrete slabs 320 and 330, Do. It is preferable that the blocking protrusions F1 and F2 of the first and second unit concrete slabs 320 and 330 are formed in the same shape and size. The blocking protrusions F1 and F2 are formed in the shape of a square bar having a square cross section and the length corresponds to the width of the concrete plate. It is preferable that the height a of the blocking protrusions F1 and F2 is 1/4 to 1/5 of the thickness b of the unit concrete slab 300. When the unit concrete slab 300 is horizontally positioned Located below the side of the concrete plate. The front surfaces of the blocking protrusions F1 and F2 of the first and second unit concrete slabs 320 and 330 are in contact with each other when the first and second unit concrete slabs 320 and 330 are horizontally positioned, A space opened above the upper surface of the blocking protrusions F1 and F2 is formed, and the concrete is cured by being poured into the space. In such a case, it is possible to exclude mounting the formwork on the underside.

The concrete slab 300 can be manufactured in a precast factory and then transported to a site where it is to be precast at the installation site.

The concrete slab 300 is manufactured and then horizontally connected steel bars B protruding from one side of the concrete slab 300 are connected to the vertical connecting steel bars H of the first wall 100, And connecting horizontal connecting steels B protruding from the other side of the concrete slab 300 to the vertical connecting steels H of the second wall 200, respectively. The horizontal connecting steels B and the vertical connecting steels H are connected by connecting means, respectively. The connecting means may be a bolt, a nut, or the like. The reinforcing bars protruding from the upper surface of the first wall 100 and the reinforcing bars projecting to one side of the concrete slab 300 are connected to each other by using a wire or the like. The concrete slab 300 may be formed by connecting one of the horizontal connecting steels B of the concrete slab 300 and the vertical connecting steels H of the first wall 100 or the second wall 100, The horizontal connection steel members B of the concrete slab 300 and the vertical connection steel members H of the first wall 100 may be arranged in a single row and connected to each other, And the vertical connecting steels H of the first wall 100 can be arranged in two rows and connected to each other. One of the horizontal connecting steels B of the concrete slab 300 may be arranged in two rows and the vertical connecting steels H of the first wall 100 may be arranged in one row and connected to each other, The two horizontal connecting steels B of the first wall 100 are arranged in two rows and the vertical connecting steels H of the first wall 100 are arranged in two rows and connected to each other.

The plate PL is coupled to the upper end surface of the vertical connection steel H of the first and second walls 100 and 200 and the horizontal connection steel B and the vertical connection steel H of the concrete slab 300 ) Can be coupled by the connecting means.

As shown in FIG. 4, the horizontal connection steel members B of the concrete slabs 300 connected to the vertical connection steel members H of the first wall 100 and the vertical connection steel members H thereof, A concrete structure is used to connect the upper surface of the wall body 100 and the side surface of the concrete slab 300 with concrete and a concrete is laid and cured in the formwork so that the first wall 100 and one side of the concrete slab 300 are connected . The horizontal connection steel members B of the concrete slabs 300 connected to the vertical connection steel members H of the second wall member 200 and the vertical connection steel members H are wound around the upper surface of the second wall member 200, The concrete is installed on the other side of the concrete slab 300 to connect the concrete to the concrete, and the concrete is laid and cured on the concrete to connect the second wall 200 and the other side of the concrete slab 300. The first wall 100 and the concrete slab 300 may be connected after the second wall 200 and the concrete slab 300 are connected.

The concrete slab 300 is preferably in the form of a horizontal plate having a uniform thickness.

Also, the concrete slab 300 may be formed in such a shape that the upper surface is flat and the lower surface is curved.

Meanwhile, as shown in FIG. 7, the concrete slab 300 may be formed in a curved plate shape having a uniform thickness.

8 is a flowchart showing a second embodiment of a method of constructing a concrete structure having a concrete slab according to the present invention. 9, 10 and 11 are process drawings showing a second embodiment of a method of constructing a concrete structure having a concrete slab according to the present invention.

As shown in FIGS. 8, 9, 10 and 11, the second embodiment of the method of constructing a concrete structure with a concrete slab according to the present invention comprises: The step of constructing the 1,2 wall 100 and the pier 400 proceeds.

The first wall 100 and the second wall 200 are spaced apart from each other and the bridge 400 is positioned between the first and second walls 100 and 200. The first and second walls 100 and 200 and the bridge pier 400 are respectively formed of a foundation 110, 210 and 410 located on the ground and an upper part of the foundation 110, 210 and 410 230 and 430 formed on the connecting portions 120, 220 and 420 and the connecting portions 120 and 220 and 420. The connecting portions 120 and 220 may be formed of the same material. A plurality of vertically connected steel materials H are provided on the upper surfaces of the body portions 130, 230 and 430. The first and second walls 100 and 200 having a plurality of vertically connected steel plates H and the bridge pier 400 are constructed in the same manner. The method in which the first and second walls 100 and 200 and the bridge pier 400 are constructed is the same as the method in which the first wall 100 of the first embodiment is constructed. Therefore, detailed description is omitted.

The first and second concrete slabs 300A and 300B having a plurality of horizontally-connected steel members B protruding from one side and protruding horizontally connected steel members B from the other side are manufactured. The first and second concrete slabs 300A and 300B preferably have the same size and shape. It is preferable that a plurality of horizontal connection steels B provided on both sides of the first concrete slab 300A have the same size and shape. Also, it is preferable that a plurality of horizontal connection steels B provided on both side surfaces of the second concrete slab 300B have the same size and shape. For convenience of explanation, the horizontal connecting steels B protruding from one side of the first and second concrete slabs 300A and 300B are referred to as first horizontal connecting steels B and the first and second concrete slabs 300A The horizontal connecting steels B protruding from the other side of the second horizontal connecting steel members B are referred to as second horizontal connecting steels B.

The first and second concrete slabs 300A and 300B are preferably the same as those of the concrete slab 300 of the first embodiment. Therefore, detailed description of the first and second concrete slabs 300A and 300B will be omitted.

10, the first horizontal connecting steels B of the first concrete slab 300A are connected to the vertical connecting steels H of the first wall 100, respectively, The step of connecting the second horizontal connecting steels B of the slab 300A with the vertical connecting steels H of the pier 400 proceeds. The connection order can be changed. The structure in which the first horizontal connecting steels B of the first concrete slab 300A and the vertical connecting steels H of the first wall 100 are connected is the same as that of the horizontal connecting steels of the concrete slab 300 of the first embodiment B and the vertical connection members H of the first wall 100 are connected to each other. The second horizontal connecting steels B of the first concrete slab 300A and the vertically connecting steels H of the piers 400 are connected by a connecting means. The connecting means can be bolts and nuts. The reinforcing bars projected on one side of the first concrete slab 300A and the reinforcing bars projecting on the upper surface of the bridge pillar 400 are connected to each other by wire or the like.

The first horizontal connecting steels B of the second concrete slab 300B are connected to the vertical connecting steels H of the second wall 200 and the second horizontal connecting steels B of the second concrete slab 300B (B) to the vertically connected steel plates (H) of the bridge pier (400). The connection order can be changed. The structure in which the first horizontal connecting steels B of the second concrete slab 300B and the vertical connecting steels H of the second wall 200 are connected is the same as the horizontal connecting steels of the concrete slab 300 of the first embodiment B and the vertical connection members H of the first wall 100 are connected to each other. The second horizontal connecting steels B of the second concrete slab 300B and the vertically connecting steels H of the piers 400 are connected by a connecting means. The connecting means can be bolts and nuts. The reinforcing bars projected on one side of the second concrete slab 300B and the reinforcing bars projected on the upper surface of the bridge pillar 400 are connected to each other by wire or the like.

On the other hand, the plate PL is coupled to the upper end surface of the vertically-connected steel material H of the pier and the plate PL of the vertically connected steel material H and the second horizontal connected steel material B of the first concrete slab 300A And the plate PL of the vertically connected steel material H and the second horizontal connected steel material B of the second concrete slab 300B are coupled by the connecting means. At this time, when the second horizontal connecting steel material B of the first concrete slab 300A is positioned on one side of the plate PL and the second horizontal connecting steel material B of the second concrete slab 300B is located on the other side of the plate PL It is preferable that the end surfaces of the two second horizontal connecting steels B are in contact with each other.

A structure for connecting the first horizontal connecting steels B of the first concrete slab 300A to the vertical connecting steels H of the first wall 100 and the structure for connecting the first horizontal connecting steels B of the second concrete slab 300B, (B) of the second wall 200 and the vertical connection steel H of the second wall 200 are respectively the same as those of connecting the horizontal connection steels of the concrete slab of the first embodiment to the vertical connection steels of the first wall . The structure for connecting the first horizontal connecting steels B of the first concrete slab 300A and the vertical connecting steels H of the first wall 100 may be, The connecting steels B and the vertically connecting steels H of the first wall 100 may be arranged in one row and connected to each other and one horizontal connecting steel material B of the first concrete slab 300A may be connected to one The vertical connecting steels H of the first wall 100 arranged in rows can be arranged in two rows and connected to each other. In addition, one of the horizontal connecting steels B of the first concrete slab 300A may be arranged in two rows and the vertical connecting steels H of the first wall 100 may be arranged in one row and connected to each other, The horizontal connecting steels B of the slab 300A are arranged in two rows and the vertical connecting steels H of the first wall 100 are arranged in two rows and connected to each other.

11, the first wall 100 is formed so as to surround the vertically connected steel plates H of the first wall 100 and the first horizontal connected steel plates B of the first concrete slab 300A, And one side of the first concrete slab 300A is connected by concrete and the first horizontal connection steel B of the second concrete slab 300B and the vertical connection steel H of the second wall 200 are connected to each other, The upper surface of the second wall body 200 and one side surface of the second concrete slab 300B are connected by concrete so as to surround the first concrete slab 300A and the second horizontal connecting steels B of the first concrete slab 300A and the second concrete slab 300B of the second concrete slab 300B, The second horizontal connecting steels B of the first bridge 300B and the vertical connecting steels H of the bridge 400 are connected to each other by concrete.

That is, the upper surface of the first wall 100 and one side of the first concrete slab 300A are molded and then the concrete is laid and cured to form the upper surface of the first wall 100 and the upper surface of the first concrete slab 300A Connect the side with concrete. Then, the upper surface of the second wall 200 and one side of the second concrete slab 300B are molded and then the concrete is laid and cured to form the upper surface of the second wall 200 and one side of the second concrete slab 300B To concrete. The other side of the first and second concrete slabs 300A and 300B and the upper surface of the bridge pier 400 are molded and then laid and cured so that the other side of the first and second concrete slabs 300A and 300B The side surface and the upper surface of the bridge pier 400 are connected by concrete. The order of connecting the first wall 100, the first concrete slab 300A, the second wall 200, the second concrete slab 300B and the bridge pier 400 to concrete may be changed.

Further, a coated layer (C) coated with concrete can be further formed on the upper plate including the first and second concrete slabs (300). The coating layer may be formed of an ascon.

The first and second concrete slabs 300A and 300B are preferably in the form of a horizontal plate having a uniform thickness. In addition, the first and second concrete slabs 300A and 300B may have a top surface and a bottom surface, respectively.

Meanwhile, as shown in FIG. 12, the first and second concrete slabs 300A and 300B may be formed in a curved plate shape having a uniform thickness. At this time, the vertically-connected steel material H provided at the upper part of the bridge pier 400 is protruded so that the upper surface of the vertically-connected steel material H is slightly higher than the upper surface of the piercings 400 or the upper surface of the piercings 400 . The end surface of the second horizontal connecting steel material B of the first concrete slab 300A and the end surface of the second horizontal connecting steel material B of the second concrete slab 300B are connected to the vertical connecting steel material H And the end of the second horizontal connecting steel material B of the first concrete slab 300A and the end of the second horizontal connecting steel material B0 of the second concrete slab 300B are connected to each other by the connecting steel E .

Hereinafter, the operation and effects of the concrete slab according to the present invention, the method of manufacturing the concrete slab, and the method of constructing a concrete structure including the concrete slab will be described.

The concrete structure having the concrete slab according to the present invention is installed in a river so that a pedestrian or a vehicle can cross the river. In this case, the concrete structure is a rammen bridge, and the ends of the roads are respectively supported on the back surfaces of the first and second walls 100 and 200 of the ramen bridge.

The concrete slabs 300 are lifted up after the first and second walls 100 and 200 and the concrete slabs 300 are manufactured. The horizontal connection steels B protruded on both side surfaces of the first and second walls 100 and 200 are connected to each other and then a mold is installed on the connection part, Therefore, the process of producing the concrete structure with the slab is simple, and the whole concrete structure with the slab is divided into the walls and the upper plate without pouring and curing the entire concrete structure. In addition, since the structure of the formwork is small and simple, it is easy to install the formwork Time to install and dismantle the house Fu is shortened.

The horizontal connecting steels B and the vertically connecting steels H are disposed between the first and second walls 100 and 200 and the concrete slab 300 and between the bridge pier 400 and the concrete slab 300, So that the structural strength of the concrete structure is strengthened.

Also, since the concrete slab (s) 300 constituting the upper plate of the concrete structure can be manufactured by precast at the installation site or can be manufactured in the factory by precast and can be transported to the installation site, the concrete slab So that it can be freely manufactured without being admitted at the production place.

In addition, when the concrete slab 300 is large, the present invention forms unit concrete slabs and then connects the unit concrete slabs together to produce a concrete slab. Therefore, the size of the slabs can be adjusted according to the size of the slabs. Design and construction can be freely adjusted to the position.

100; A first wall 200; The second wall
300; Concrete slabs 300A; The first concrete slab
300B; A second concrete slab 400; pier

Claims (7)

delete delete Constructing the first and second walls protruding from the vertically connected steels;
A concrete plate having a reinforcing structure with reinforcing bars disposed therein, a reinforcing plate having a length smaller than the length of the concrete plate and being provided on the concrete plate so as to protrude from both sides in the longitudinal direction of the concrete plate, Fabricating a concrete slab comprising a plurality of horizontal connected steels;
Connecting one of the horizontal connecting steels of the concrete slab to the vertical connecting steels of the first wall and connecting the other one of the horizontal connecting steels of the concrete slab to the vertical connecting steels of the second wall; And
The upper surface of the first wall and one side surface of the concrete slab are connected by concrete so as to enclose the vertical connecting steels of the first wall and the one horizontal connecting steel of the concrete slab and the vertical connecting steels of the second wall and the concrete slab Connecting the upper surface of the second wall and the other side of the concrete slab to the concrete so as to surround the other one of the horizontal connection steel members of the concrete slab,
The first and second walls each having a plurality of vertically connected steel members protruding from opposite sides of a concrete plate having reinforcing bars disposed therein; Fabricating a foundation having a plurality of vertically connected steel members protruding from the upper surface of a concrete body having reinforcing bars arranged therein, on a foundation foundation; Connecting the vertical connecting steels of the main body part and the vertical connecting steels of the base part by vertically setting the main body part; Providing a mold so that concrete can be placed between the lower surface of the concrete plate of the main body portion and the upper surface of the concrete body of the base portion; Placing the concrete in the mold and curing the concrete to connect the body and the foundation,
A plurality of vertically connected steel plates provided on both side surfaces of the concrete plate of the main body are respectively smaller than the length of the concrete plate and are respectively projected on both longitudinal sides of the concrete plate,
The vertical connection steel of the first and second walls and the horizontal connection steels of the concrete slab have a cross-sectional shape composed of two horizontal parts positioned in parallel with each other and a vertical part connecting the middle parts of the two horizontal parts to each other However ,
The concrete slab may include:
The method comprising the steps of: preparing first and second unit concrete slabs each having a plurality of horizontally-connected steel members on a side surface thereof;
Connecting the horizontal connected steels of the first unit concrete slab and the horizontal connected steels of the second unit concrete slab to each other;
And connecting the first and second unit concrete slabs to concrete so as to surround the horizontal connection steel members of the first and second unit concrete slabs,
The concrete slab includes a first unit concrete slab having a plurality of first horizontal connecting steels protruded on both sides thereof; A second unit concrete slab in which a plurality of second horizontal connecting steels protrude from both sides; Connecting means for connecting the first and second horizontal connecting steels of the first and second unit concrete slabs; And a connecting concrete part for connecting the first and second unit concrete slabs while enclosing one of the first and second horizontal connecting steels of the first and second unit concrete slabs,
Wherein the first and second horizontal connecting steels are section steel having a cross-sectional shape composed of two horizontal parts positioned in parallel with each other and a vertical part connecting the middle parts of the two horizontal parts to each other. A method of constructing a concrete structure. delete The method as claimed in claim 3, wherein the vertically-connected steel materials provided on both sides of the body portion are arranged in two rows, and the vertically-connected steel materials of the base portion are arranged in two rows. delete delete

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