KR20150027879A - A structure of reinforcing rods cages for connecting of rotary type - Google Patents

Abstract

The present invention relates to a rotating connection structure of reinforcing bar cage for vertically connecting reinforcing bar cages, wherein the reinforcing bar cage is integrated with ring-shaped circular flanges (20, 30) formed on upper and lower end parts of a metal mesh (10) and having planar surfaces with a predetermined width. The lower flange (20) is connected with a lower end part of the metal mesh (10) and has coupling holes (22) formed on the planar surface in a predetermined width and length along the planar surface at regular intervals. The upper flange (30) is connected with an upper end part of the metal mesh (10) and includes a plurality of ㄱ-shaped wedges (32) protruding from an upper surface upward to be inserted into the coupling holes (22) of the lower flange (20) on the same vertical lines as the coupling holes (22). The ㄱ-shaped wedges (32) vertically connecting the reinforcing bar cages and formed on the upper flange (30) of the lower reinforcing bar cage are inserted into the coupling holes (22) of the lower flange (20) of the upper reinforcing cage, and then are coupled to each other to prevent the reinforcing bar cages from being vertically separated from each other by rotating the upper and lower reinforcing bar cages at a predetermined angle. Therefore, the upper and lower reinforcing bar cages can be fixated and connected by being fastened on the upper and lower flanges (20, 30).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cage structure for a rotating coupling,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary coupling steel cage structure, and more particularly, to a rotary coupling steel cage structure in which a lower end portion of an upper cage is positioned at an upper end portion of a lower cage, .

In general, the foundation construction of bridges is often carried out in the field, and this is often referred to as cast-in-place piles.

The drilled pile is constructed by forming a large diameter hole in the foundation ground, inserting the steel cage manufactured in this hole and then placing the concrete.

However, the rebar cage is constructed with a certain length by assembling the vertical reinforcing bars and the reinforcing bars together in a separate manufacturing site.

The rebar cage thus manufactured is transported to the site using equipment such as a crane and installed inside the casing installed in the foundation ground.

However, in the process of installing the reinforcing cage, the plurality of reinforcing cages are assembled by welding, lap joint, and coupler. In this case, it is very difficult to align the reinforcing cage vertically.

In order to achieve this, a reinforcing cage structure as disclosed in Japanese Laid-Open Patent Publication No. 2011-0038587 has been suggested. However, since the construction procedure of the vertical reinforcing bars and the circular flange is not sufficient and the circular flange does not firmly hold the vertical reinforcing steel, There was a problem that caused deformation of the structure,

Recently, a circular flange is disposed on the upper and lower sides of the reinforcing net structure through the use of the patent registration No. 1184226 (2012.09.13, 2012, name: a method using a connecting device for a reinforcing net structure and a connecting device for a reinforcing net structure) proposed by the present applicant And the end of the vertical steel reinforcing bar is welded to the fixing groove formed uniformly along the outer circumferential surface of the circular flange so that the vertical steel reinforcing bars can be vertically aligned with each other. And bolt holes are formed so that the upper and lower circular flanges are fastened by bolts and nuts.

However, in the prior art of the present invention, since the circular flange has to be connected to each other by bolts and nuts, this connection operation not only requires a large number of manpower but also causes a delay in operation.

Particularly, in the prior art, there is an uneconomical problem due to the extension of the labor input and the construction period due to the welding of the vertical reinforcing bars to the straight line.

Patent registration No. 1184226 (2012.09.13.)

The present invention has been made to solve the above problems, and it is an object of the present invention to provide a method of manufacturing a steel reinforcing cage, which is characterized in that, in a coupling groove formed in a circular flange on a lower end side of an upper side reinforcing cage, The present invention has a main object of providing a rotary coupling cage structure that can more easily and fastly assemble by making the wedge fit and then tightly connecting the upper side reinforcing cage at a certain angle so as to prevent separation of the wedge wedge .

Another object of the present invention is to provide a rotary coupling cage structure that maximizes the economic effect by shortening the manpower and the time required for assembly of the steel cage.

In order to accomplish the above object, a rotary coupling cage structure of the present invention is characterized in that a plurality of vertical reinforcing bars are formed at regular intervals with a predetermined radius, and a reinforcing bar mesh is formed at the outer side of the vertical reinforcing bars, A reinforcing cage for vertically connecting a reinforcing cage formed integrally with a ring-shaped circular flange having a horizontal plate surface with a predetermined width so that an end portion of the vertical reinforcing bars of the reinforcing net is welded along the outer circumference at an upper end portion and a lower end portion of the reinforcing cage In the coupling structure, the lower flange connected to the lower end of the reinforcing net may be formed with a plurality of holes through which a plate surface is vertically penetrated with a predetermined width and length while being spaced apart from each other by a predetermined distance along a horizontal plane, The upper flange is connected to the lower flange, Shaped wedge so as to protrude upward from the upper surface so as to be able to be inserted into the binding hole on the upper flange of the lower side reinforcing cage while vertically connecting the reinforcing cage to the upper flange of the lower side reinforcing cage Shaped wedge is inserted through the hole formed in the lower flange of the upper side reinforcing cage so as to be coupled with the upper side reinforcing cage so as to prevent vertical separation between the reinforcing cages by rotating the upper side reinforcing cage at a certain angle, The bolts are fastened to the flange at a plurality of positions so that the upper and lower cages are fixedly connected.

According to the rotary coupling cage structure of the present invention in accordance with the above-described construction, the steel cages separately prepared are simply brought into close contact with each other between the circular flanges in the vertical direction, and are prevented from being separated in the vertical direction between the circular flanges Thereby making it possible to provide a quick and easy connection structure between the reinforcing cages.

In addition, the present invention can minimize manpower and work time for coupling between the steel cages, thereby achieving more economical pile construction.

1 is an exploded perspective view of a rotatable coupling steel cage according to the present invention;
Figure 2 is a perspective view of a combined coupling of a rotatable coupling steel cage according to the present invention
3 is a plan view illustrating a lower flange of a rotatable coupling steel cage structure according to the present invention;
4 is a plan view illustrating an upper flange of a rotary coupling steel cage structure according to the present invention;
5 is a cross-sectional view showing a recessed structure in an upper flange of a rotatable coupling steel cage structure according to the present invention;
6 is an enlarged view showing another embodiment of a bracket wedge in an upper flange of a rotary coupling cage structure according to the present invention.
Fig. 7 is a perspective view showing a connection structure of a reinforcing cage according to the present invention.
8 and 9 are side cross-sectional views illustrating a coupling structure of a rotatable coupling steel cage according to the present invention.
10 is a perspective view illustrating an assembled state of the rotatable coupling steel cage according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a rotary coupling steel cage structure according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating a rotary coupling cage according to an embodiment of the present invention. FIG. 2 is a perspective view illustrating a rotary coupling cage according to the present invention. Referring to FIG. 1, a reinforcing cage of the present invention includes a reinforcing bar 10, And a lower flange 30, which is also contrary to the configuration of the prior art which is a line registration invention.

The double reinforcing bar 10 is provided with a plurality of vertical reinforcing ribs 11 at predetermined intervals in a predetermined radius and a horizontal or helical shape is formed on the outside of the vertical reinforcing ribs 11, And is integrally joined by welding.

A ring-shaped circular flange having the same diameter and size is integrally joined to the upper and lower ends of the reinforcing bar 10 by welding as a lower flange 20 and an upper flange 30, respectively.

That is, the upper flange 20 and the upper flange 30 are fixed at their upper and lower ends of the vertical reinforcing bars 11 of the reinforcing bar 10 by welding, respectively, at regular intervals along the outer peripheries, thereby forming a single reinforcing cage do.

FIG. 3 is a plan view illustrating a lower flange of the rotary coupling cage structure according to the present invention. The lower flange 20 has a plate surface such that the lower ends of the vertical reinforcing bars 11 of the reinforcing bar 10 are inserted into the outer periphery of the lower flange 20, So that the reinforcing bar welding hole 21 is formed with a predetermined diameter and the lower reinforcing bar 11 is inserted into the reinforcing bar welding hole 21 so that the lower reinforcing bar 11 is inserted into the reinforcing bar welding hole 21 by welding.

However, it is more preferable that the reinforcing bar welding hole 21 in the lower flange 20 is formed to be opened to the outside of the plate surface so that the insertion of the vertical reinforcing bar 11 is facilitated.

In addition, the lower flange 20 is spaced apart from the lower flange 20 by a predetermined width and length, and the plate surface is vertically penetrated to form the binding hole 22.

The binding holes 22 are repeatedly formed at regular intervals at the same radius, and the binding holes 22 are formed in a rectangular shape or an arc shape in which the inner and outer circumferential surfaces and the outer circumferential surfaces are concentrically formed with different diameters.

The upper flange 30 provided with the lower flange 20 has the same shape and size.

FIG. 4 is a plan view illustrating an upper flange of a rotatable coupling steel cage structure according to the present invention, and FIG. 5 is a cross-sectional view illustrating a recessed structure of an upper flange of a rotary coupling cage structure according to the present invention.

As shown in the figure, the upper flange 30 of the present invention is substantially similar to the upper flange 30, but differs from the lower flange 20 in that the wedge 32 is formed.

The upper flange 30 has a reinforcing steel welding hole 31 formed in the same shape and spacing as those of the reinforcing steel welding hole 21 formed in the lower flange 20 along the outer periphery as in the case of the lower flange 20 .

The lower flange 20 is formed with a hole 22 vertically penetrating a predetermined width and length along the plate surface while the upper flange 20 is provided with a hole 22 in the lower flange 20, Shaped wedge 32 is integrally formed so as to protrude upwards on the same vertical line as that of the wedge-

The upper portion of the wedge 32 formed on the upper flange 30 forms a horizontal portion 32a parallel to the plate surface of the upper flange 30. The horizontal portion 32a is engaged with the lower flange 30, (22) to be vertically penetrable.

One end of the horizontal portion 32a is vertically bent downward to integrally connect to the plate surface of the upper flange 30 to form a vertical portion 32b. Most preferably less than the thickness.

6 is an enlarged view showing another embodiment of a bracket type wedge in an upper flange of a rotary coupling cage structure according to the present invention.

Shaped wedge 32 of the upper flange 30 has a predetermined height at an intermediate portion of the upper surface of the horizontal portion 32a for stable engagement with the binding hole 22 of the lower flange 20, It is most preferable that the lower surface of the horizontal portion 32a is formed such that a certain angle is inclined upward from a predetermined position on the side of the vertical portion 32b to the tip side.

A plurality of vertical reinforcing bars 11 are welded between the lower flange 20 and the upper flange 30 so that the reinforcing bars 12 are arranged in a helical shape from the outside, And the vertical reinforcing bars 11 connected between the vertical reinforcing bars 11 by the band reinforcing bars 12 are formed on the outer circumferential surfaces of the lower flange 20 and the upper flange 30, The lower end and the upper end are fitted and inserted into the upper and lower portions 21 and 31, and are fixedly connected by welding.

Particularly, in the case where the bottom flange 20 and the upper flange 30 of the present invention are rotated at a predetermined angle while the bracket wedge 32 is bridged and connected to the coupling hole 22 when the reinforcing cage is engaged, A plurality of bolting fastening holes 23 and 33 are formed so that the coupling force in the vertical direction between the flange 20 and the upper flange 30 can be strengthened.

When the relatively small diameter structure is constructed, the reinforcing steel welding holes 21 and 31, to which the vertical reinforcing bars 11 are welded on the plate surfaces of the lower flange 20 and the upper flange 30, Shaped wedges 32, as shown in FIG.

The operation according to the connection structure of the rotary coupling cage of the present invention according to the above structure will be described as follows.

FIG. 8 is an enlarged perspective view illustrating a connecting structure of a reinforcing cage according to the present invention. FIG.

As shown in the drawing, the reinforcing cages formed by the combination of the reinforcing net 10, the lower flange 20 and the upper flange 30 are connected to each other in the vertical direction. The reinforcing cage is formed by the upper flange 30, And the lower flange 20 on the lower end side of the upper side reinforcing cage is placed on the lower side flange 30.

9 and 10 are side cross-sectional views illustrating a coupling structure of a rotatable coupling steel cage according to the present invention.

The coupling between the reinforcing cages is performed by moving the upper side reinforcing cage downward using a crane or the like so as to come close to the upper side of the lower side reinforcing cage while the engaging holes 22 formed in the lower side flange 20 on the lower side of the upper side reinforcing cage, Shaped wedge 32 formed on the upper flange 30 on the upper end side of the side reinforcing cage.

In this state, when the upper side reinforcing cage is moved downward to be placed on the upper end of the lower side reinforcing cage, the upper side flange 30 of the lower side reinforcing cage is guided through the binding holes 22 formed in the lower flange 20 of the upper side reinforcing cage Shaped wedge 32 formed on the upper flange 30 protrudes from the upper surface of the upper flange 30 and the lower flange 20 of the upper side reinforcing cage and the upper flange 30 of the lower side reinforcing cage The plate surfaces between the flanges 30 are in close contact with each other due to the load of the upper side reinforcing cage.

In the state where the horizontal portion 32a of the wedge 32 is projected from the upper flange 30 of the lower side reinforcing cage, the upper side reinforcing cage is moved in one direction, that is, in the direction of forming the vertical portion 32b of the wedge 32 .

One end face of the binding hole 22 formed in the lower flange 20 of the upper side reinforcing cage by the rotation of the upper side reinforcing cage is connected to the lower flange 30 of the lower flange 30 of the lower side reinforcing cage And the upper side reinforcing cage can no longer be rotated when it is caught by the vertical portion 32b.

When the upper side reinforcing cage rotates, one end of the binding hole 22 formed in the lower flange 20 slides horizontally along the lower space on the horizontal portion 32a side of the wedge- The horizontal portion 32a of the lower flange 20 is inclined downward at a predetermined angle from the front end of the lower face so that the height of the space between the lower end of the horizontal portion 32a and the upper flange 30 is larger than the plate thickness of the lower flange 20 So that the upper side reinforcing cage can be smoothly rotated.

However, since the height of the lower space on the horizontal portion 32a side of the wedge-shaped wedge 32 is the same as the thickness of the lower flange 20 at the end of the inclined surface of the horizontal portion 32a, I will not go.

Accordingly, when the upper side reinforcing cage is rotated strongly instantaneously, it is quickly inserted into the inclined portion of the horizontal portion 32a of the wedge-shaped wedge 32 without a large resistance, and the lower portion of the horizontal portion 32a The one end of the fastening hole 22 of the lower flange 20 can be inserted more smoothly and tightly into the narrower space and the upper side reinforcing cage is rotated with a stronger force even though it is not easily inserted, Is firmly inserted and fixed in the binding hole 22.

When the upper side reinforcing cage is rotated as much as possible, the vertical reinforcing bars 11 of the upper side reinforcing cage and the vertical reinforcing bars 11 of the lower reinforcing cage are positioned on a straight line, Since the plurality of bolt fastening holes 23 and 33 formed in the flange 20 and the upper flange 30 are mutually communicated on the same vertical line, bolts and nuts are used to firmly connect the flanges.

The main purpose of the joint structure by the bolt and the nut is to prevent a situation in which the binding state is released or flowed by the rotation in the opposite direction.

Since the connection between the flanges using bolts and nuts is designed to prevent the flow in the direction of rotation between the flanges only, it is preferable that the connection portions by bolting are formed to a minimum at only 2 to 4 places, The flow is prevented by the wedge-shaped wedge 32.

11 is a perspective view illustrating a coupled state of a rotatable coupling steel cage according to the present invention.

As shown in the figure, when the plurality of steel cages are vertically connected, the construction time is further shortened while minimizing the manpower required, thereby greatly reducing the labor cost and the construction cost.

In addition, it is possible to completely prevent loosening or detachment in the vertical direction between the steel cages due to the corrosion of the bolt and the nut, thereby improving the reliability of the accurate construction.

10: reinforcing net 11: vertical reinforcing steel
12: belt reinforcement 20: bottom flange
21: reinforcing steel welding hole 22: binding hole
23: bolt fastening hole 30: upper flange
31: reinforcing steel welding hole 32:
32a: Horizontal part 32b: Vertical part
33: Bolt tightening hole

Claims (7)

A plurality of vertical reinforcing bars 11 are formed at regular intervals in a predetermined radius and the upper and lower ends of the reinforcing bars 10 are horizontally or spirally arranged outside the vertical reinforcing bars 11, Like circular flanges 20 and 30 having a horizontal plate surface of a predetermined width are integrally formed so that the end portions of the vertical reinforcing bars 11 of the reinforcing bar 10 are welded along the outer circumference, And a reinforcing cage coupling structure,
Bottom flanges 20 connected to the lower end of the reinforcing net 10 are formed with binding holes 22 so as to be spaced apart from each other along a horizontal plate surface and vertically penetrate the plate surface with a predetermined width and length,
The upper flange 30 connected to the upper end of the reinforcing bar 10 is provided with a hooking hole 22 extending from the upper face so as to be inserted into the binding hole 22 on the same vertical line as the binding hole 22 formed in the lower flange 20. [ And a reinforcing cage for integrally forming a plurality of wedge-shaped wedges 32 so as to protrude upward,
The wedge-shaped wedge 32 formed on the upper flange 30 of the lower side reinforcing cage passes through the fastening holes 22 formed in the lower flange 20 of the upper side reinforcing cage while vertically connecting the reinforcing bars The upper side reinforcing cage is rotated at a predetermined angle so that the upper side reinforcing cage is coupled so as to prevent the upper and lower separation between the reinforcing cages,
The upper flange (30) and the lower flange (20) are bolted to each other at a plurality of positions to fix and connect the upper and lower cages.

The height of the space between the lower surface of the horizontal portion 32a of the wedge 32 and the upper surface of the upper flange 30 is not greater than the thickness of the plate surface of the lower flange 20, Cage structure.
The wedge-shaped wedge 32 is formed such that the lower surface of the horizontal portion 32a is formed so as to be gradually upwardly inclined toward the tip side between the tip end and the vertical surface 32b, And a predetermined length from the front end of the lower flange (32a) to the vertical portion (32b) side is formed larger than the plate thickness of the lower flange (20).
The rotary coupling cage structure as set forth in claim 1, wherein the intermediate wedge (32) has an upwardly curved intermediate portion in a direction of a longer length of the upper surface.
The rotary joint according to claim 1, wherein a bolt fastening hole (23, 33) for connecting the lower flange (20) and the upper flange (30) Reinforced cage structure.
The reinforcing steel welding tool according to claim 1, wherein the reinforcing steel welding holes (21, 31) for welding the ends of the vertical reinforcing bars (11) at the lower flange (20) and the upper flange (30) Respectively, of the cage structure.
The rotary coupling cage structure according to claim 1, wherein the vertical reinforcing bars (11) of the upper side reinforcing cage and the vertical reinforcing bars (11) of the lower side reinforcing cage are positioned on a straight line in a state where the upper side reinforcing cage is fully rotated.

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