KR101712430B1 - Beam-Slab Pannel Joint Structure - Google Patents

Abstract

The present invention relates to a combination structure between a beam and a slab panel installed in the upper part of a pillar of a pillar type footbridge, etc., capable of enhancing quickness of combination work and structural stability of a combination state. According to the present invention, the combination structure comprises: a plurality of beams (20) including an upper surface flange (21) and a web (22) to including a T-shaped cross section, and installed in parallel at an interval; a hollow slab panel (30) which is a precast concrete (PC) panel holding both ends to the upper surface flange (21) of the beam (20) installed at an interval, and having a plurality of through-holes (31) across both ends of the panel formed in parallel; support metal fittings (40) to connect a first surface (41) fixated in contact with the lower surface of the upper surface flange (21) of the beam (20) with a second surface (42) fixated in contact with the lower surface of the hollow slab panel (30); a stud bolt (50) combined along a longitudinal central line of the upper surface flange (21) of the beam; and a strand (60) installed to pass the through-hole (31) of the hollow slab panel (30) to fixate both ends through the stud bolt (50). The plurality of hollow slab panel (30) are installed to form a continuous surface in the direction of the beam (20) and are installed at an interval in the direction orthogonal to the beam (20) by interposing the stud bolt (50) therebetween.

Description

Beam-Slab Pannel Joint Structure < RTI ID = 0.0 >

The present invention relates to a joining structure of a beam and a slab panel installed on a column top of a bridge, such as a bridge of a bridge, and is intended to improve the quickness of the joining operation and the structural safety of the joining state.

Footbridge refers to a bridge whose purpose is limited to the passage of pedestrians (and, in some cases, light vehicles such as bicycles). These bridges are installed variously in bridges, rivers, shores, inner city walks, mountainous areas, and the like for bridges, retaining walls or the like by means of a cantilever structure or supported by pillars.

The present invention relates to a bridge structure supported by pillars, and the basic structure of a bridge such as a foundation, a column, a girder, a beam, and a slab should be provided. The coupling structure between each of the listed components can be variously derived, and the common orientation of the coupling structure techniques can be construed as workability and safety.

1. Patent document 10-2015-0015094 "Beam upper reinforcing member, beam provided with upper beam reinforcing member, and construction structure using the same" 2. Patent Application No. 10-0916973 "Method of Construction and Structure of Prestressed Concrete Pavement"

It is an object of the present invention to provide a beam-slab panel coupling structure capable of easily coupling a slab panel onto a beam and ensuring safety in a coupled state.

The present invention is characterized in that: a beam (20) composed of a top flange (21) and a web (22) and having a T-shaped cross section and having a plurality of parallel spaced apart; A PC (Precast Concrete) panel mounted on a top surface flange (21) of a beam (20) spaced apart at both ends, comprising: a hollow slab panel (30) in which a plurality of through holes (31) crossing both ends of the panel are formed in parallel; A supporting hardware 40 connected to a first surface 41 fixed to the lower surface of the upper surface flange 21 of the beam 20 and a second surface 42 fixed in contact with the lower surface of the hollow slab panel 30; A stud bolt (50) coupled along the longitudinal centerline of the top flange (21) of the beam (20); And a straddle (60) installed across the through hole (31) of the hollow slab panel (30) and having both ends fixed to the stud bolt (50); Wherein a plurality of the hollow slab panels 30 are provided so as to form a continuous surface in the direction of the beam 20 and the stud bolts 50 are disposed in a direction orthogonal to the beams 20 Spaced beam - slab panel coupling structure. Beam-slab panel coupling structure ".

The present invention further includes a tension member (70) coupled along a bottom centerline of the hollow slab panel (30) parallel to the longitudinal centerline of the beam (20). , Wherein the hollow slab panel (30) is provided with an inclined hole (32) formed in the through hole (31) in the direction of the tension member (70); And the straddle 60 extends from the one side of the hollow slab panel 30 through the through hole 31 and the inclined hole 32 to the tension member 70 and turns to the other inclined hole 32 And the through-hole 31. The beam-slab panel coupling structure of the beam-slab panel structure of FIG.

In this case, the hollow slab panel 30 includes a curved tube 33 embedded in a portion where the through hole 31 and the inclined hole 32 are connected to each other; As shown in FIG.

In addition, the tension member (70) includes a bolt rod (71) formed with upper and lower male threads in different directions; A transverse shaft 72 protruding from both sides of the bolt rod 71; An upper sleeve nut (73) coupled to a lower surface of the hollow slab panel (30) and having a female screw groove corresponding to an upper male screw thread of the bolt rod (71); A lower sleeve nut 74 formed on the inner surface thereof with a female screw groove corresponding to a lower male screw thread of the bolt rod 71; And a nut head (75) coupled to the lower end of the lower sleeve nut (74) to engage the strand (60); And when the bolt rod 71 is turned clockwise or counterclockwise using the abscissa 72, the upper and lower sleeve nuts 73 and 74 are engaged with the bolts 71 It is possible to constitute such that tension is applied to the strand 60 by moving in a longitudinal direction and rotating around a thread.

According to the present invention,

1. Precast Concrete hollow slab panel is mounted and fixed on the top of the beam to reduce noise and vibration due to walking on the bridge.

2. It is possible to increase the safety of the slab panel installation state by applying tension to the strand and weaving multiple hollow slab panels to the beam.

3. Hollow slab panel It is possible to increase the convenience of installation work of hollow slab panel by adjusting the tensile force applied to stranes by the tension member joined to the underside.

FIG. 1 shows a fitting structure of a beam in which a girder having a rectangular cross section and a rectangular insertion port are formed in a web.
[Fig. 2] shows a fitting structure of a beam in which a semicircular-shaped insertion port is formed in a girder and a web with a circular cross section.
[Fig. 3] shows a fitting structure of a beam in which a square-shaped insertion port is formed in a girder and a web with a square cross-section and the left and right members are hinged together.
FIG. 4 shows a fitting structure of a beam in which a semicircular-shaped insertion hole is formed in a girder and a web with a circular cross section, and the left and right members are hinged together.
5 and 6 show a structure in which a hollow slab panel mounted on a top surface flange of a beam is coupled.
[7] and [8] show a structure in which a hollow slab panel is fixedly attached by a tension applied with a tension.
[Fig. 9] shows an installation structure of a tension member for applying tension to a straddle.
10 shows a process of applying a tension to the strand with a tension member.

On the foot bridge, a pillar (pier) is erected on the foundation, and a girder is laid between the pillar and the pillar. At the upper part of the girder, a beam is installed in a direction orthogonal to the girder, a slab is installed on the beam, and a railing is provided along both sides of the slab.

The present invention relates to a coupling structure of a girder and a beam, and a structure in which a slab is provided on a beam is described in the claims.

In addition, although the present invention is mainly applied to bridge-to-bridge, the girder-beam interfitting structure provided by the present invention and the girder-beam interfitting structure using a hinged beam can also be applied to a general bridge and a building.

 Accordingly, it is to be understood that the scope of the present invention should be determined based on whether the object of construction is a constituent element or a combination relation between constituent elements rather than what is to be constructed, and various embodiments derived from the features of the present invention are also included in the scope of the present invention .

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Ⅰ. Girder-beam coupling structure

1. Fitting structure of girder and beam

As shown in Fig. 1 and Fig. 2, the present invention is characterized in that " girder 10 installed at the upper end of a column; And the upper surface flange 21 and the web 22 are formed to have a T-shaped cross section so as to be orthogonal to the girder 10 and the web 22 is provided with a beam 20 having an insertion port 23 for receiving the girder, ; Beam coupling structure ".

The girder 10 is a structural member which is installed across a pillar (pier), and transfers the load on the bridge to the pillar. In the present invention, a PC block, quadrangular tube, circular tube, or the like can be used as a girder.

The beam 20 is a structural member installed at an upper portion of the girder 10 so as to be orthogonal to the girder 10 and transmitting a load on the bridge to the girder 10. A slab (bridge top plate) is provided on the beam 20. In the present invention, a beam having a top end flange 21 and a web 22 and having a T-shaped cross-section is applied, and the web 22 is provided with an insertion port 23 through which the girder is inserted. ) Between the girder (10) and the beam (20).

1 shows a girder-beam coupling structure of a ground joint bridge in which the cross section of the girder 10 is rectangular and the insertion hole 23 of the beam 20 is a rectangular cross- .

In this case, the stud bolt 1 is coupled to the upper portion of the girder 10, and the through hole 2 is formed in the upper surface flange 21 of the beam 20, The stud bolt 1 is inserted through the insertion hole 23 and protruded above the upper surface flange 21 through the through hole 2 of the upper surface flange 21 of the beam 20, By fitting the nut 3 to the protruding portion, the both members can be fixed as one body in a state in which the girder 10 and the beam 20 are fitted to each other.

2 shows a girder-beam coupling structure of a ground joint bridge according to the present invention, in which the cross section of the girder 10 is circular and the insertion hole 23 of the beam 20 is a semicircular cross- will be.

When a plurality of the girders 10 are provided in parallel on the column as shown in FIG. 2, a plurality of the insertion holes 23 are formed corresponding to the girders 10 to form the beams 20 on the girders 10, . Even in this case, the girder 10 and the beam 20 can be integrally combined by using separate fasteners, welding, or the like.

2. Fitting structure of girder and hinge combined beam

It is difficult to smoothly fit the girder 10 and the beam 20 due to the friction between the insertion hole 23 and the girder 10 when the girder 10 and the beam 20 are fitted together using the insertion hole 23 of the beam 20 web 22, There are many cases. Accordingly, in the present invention, the above problem is solved by constructing the beam 20 to be hinged to the left and right members.

3 shows a fitting structure of a beam 10 in which a rectangular insertion port is formed in a girder 10 and a web 22 having a rectangular cross section and the left and right members are hinged to each other.

The beam 20 of FIG. 3 is cut along the one side edge of the insertion slot 23 of the square-shaped insertion port 23 and is divided into left and right members (cut along the right edge of the insertion port in FIG. 3).

A clamp 4 having a through hole formed along the cutting line 24 of the upper surface flange 21 of the beam 20 is interdigitated to the left and right members, And the left and right members are hinged by a fixing rod 5 inserted into the through hole.

By this hinge coupling, the left member or the right member of the beam 20 can be folded upward (in Fig. 3 (a), the right member is folded up) The stud bolt 1, the nut 3 (see FIG. 3 (a)) and the bolt 2 (the bolt 3) in the state in which the girder 10 and the insertion port 23 are aligned with each other and the folded- The girder 10 and the beam 20 can be integrally fixed by means of fasteners such as screws or the like.

4 shows a fitting structure of a girder 10 having a circular cross section and a beam 20 in which a semicircular insert is formed in the web and the left and right members are hinged together.

The beam 20 of FIG. 4 is cut along the center line of the semicircular insertion hole 23 and divided into left and right members.

A clamp 4 having a through hole formed along the cutting line 24 of the upper surface flange 21 of the beam 20 is interdigitated to the left and right members, And the left and right members are hinged by a fixing rod 5 inserted into the through hole.

In this case, too, the left member or the right member of the beam 20 can be folded up by the hinge coupling (in Fig. 4, the right member is folded up) The girder 10 and the beam 20 are integrally fixed to each other by using a separate fastener or by welding in a state in which the folding member 10 is fitted to the insertion port 23, .

As described above, the hinge-coupled beam provides convenience of storage and transportation of the beam material in addition to facilitating the fitting of the beam with the girder.

3. Install the slab

4 shows a state in which the hollow slab panel 30 is partially installed on the upper surface flange 21 of the beam 20. As shown in FIG. A hollow slab panel 30 is continuously installed on the beam 20 to complete the slab of the bridge.

The present invention relates to a PC (Precast Concrete) panel in which a hollow slab panel 30 in which a plurality of through holes 31 crossing at both ends of the panel are formed in parallel is horizontally and vertically arranged Thereby completing the slab.

In the case of wood, noise and vibration due to walking and the like can cause anxiety to walk, the structural rigidity is weak, and the integration with the girder is weak. However, since the PC hollow slab panel 30 according to the present invention has a plurality of through holes 31 formed therein, it is light in weight and noise and vibration are reduced in the through holes 31 and structural rigidity can be increased, Can give a sense of stability.

Ⅱ. Beam-slab panel joining structure

1. Coupling structure between beam and slab panel

As described above, the hollow slab panel 30, in which a plurality of through holes 31 are formed parallel to both ends of the panel, is fixed and fixed on the beam 20 as a PC (Precast Concretely) panel.

The hollow slab panel 30 is mounted on the upper surface flange 21 of the beam 20 spaced at both ends as shown in Figs. 5 and 6, So that the through holes 31 are formed at right angles.

The beam 20 and the hollow slab panel 30 are coupled via the support hardware 40. The supporting hardware 40 includes a first surface 41 fixed to the lower surface of the upper surface flange 21 of the beam 20 and a second surface 42 fixed to the lower surface of the hollow slab panel 30 in contact therewith .

Also, a plurality of the hollow slab panels 30 may be integrally formed by weaving the beams 20 with the straddle 60. A stud bolt 50 is coupled to the upper surface flange 21 of the beam 20 along the longitudinal center line of the beam 20 and a strand 60 is inserted into the through hole of the hollow slab panel 30, (31), and both ends thereof are fixed to the stud bolts (50).

A plurality of the hollow slab panels 30 are provided so as to form a continuous surface in the direction of the beam 20 and spaced apart from each other with the stud bolts 50 interposed therebetween in a direction orthogonal to the beams 20.

A spacer 80 may be provided between the hollow slab panels 30 spaced apart from each other with the stud bolts 50 interposed therebetween. 5, the spacers 80 include spacing plates 81 sandwiched between the hollow slab panels 30 spaced apart by the stud bolts 50, And a mounting plate 82 coupled to the upper end of the hollow slab panel 30 and having opposite ends thereof respectively mounted on the hollow slab panel 30.

The spacers 80 serve to maintain the interval between the hollow slab panels 30 constant and to act as a stiffener against bending. When the lower end of the spacer 81 is joined to the upper surface flange 21 of the beam 20 by welding or bolting, the spacer 80 serves as a reinforcement for bending and twisting Even if the lower end of the spacer plate 81 is not engaged with the upper surface flange 21 of the beam 20, it can serve as a reinforcing member for a force to be bent at least downward by the mounting plate.

2. Structure to apply strain to the trend

The plurality of hollow slab panels 30 can not be stitched together by the straddle by simply inserting the straddle 60 through the through holes of the hollow slab panel 30 and fixing both ends thereof. As shown in FIGS. 7 and 8, tension applied to the strand 60 when tension is applied to the stud bolt 50 in the state where both ends of the strand 60 are fixed to the stud bolt 50 Which acts to force the hollow slab panel 30 against the beam 20.

A tension member (70) is coupled along the lower centerline of the hollow slab panel (30) parallel to the longitudinal centerline of the beam (20) to apply tension to the strand (60).

Accordingly, in the hollow slab panel 30, the inclined holes 32 are formed in the through holes 31 in the direction of the tension member 70 so as to form the inclined holes 32 as shown in FIG. 7 (a) And the through hole 31 and the inclined hole 32 from the one side of the hollow slab panel 30 to the tension member 70 and then passed through the inclined hole 32 and the through hole 31 on the other side, .

7 (b), a curved pipe 33 is embedded in a portion where the through-hole 31 and the inclined hole 32 of the hollow slab panel 30 are connected to each other, 60 may be passed along the curved tube 33.

As shown in FIG. 9, the tension member 70 includes a bolt rod 71 having upper and lower male threads formed in different directions; A transverse shaft 72 protruding from both sides of the bolt rod 71; An upper sleeve nut (73) coupled to a lower surface of the hollow slab panel (30) and having a female screw groove corresponding to an upper male screw thread of the bolt rod (71); A lower sleeve nut 74 formed on the inner surface thereof with a female screw groove corresponding to a lower male screw thread of the bolt rod 71; And a nut head (75) coupled to the lower end of the lower sleeve nut (74) to engage the strand (60); As shown in FIG.

The nut head 75 is configured to pass through the straddle 60 so that the straddle 60 can be prevented from being detached from the nut head 75 in the course of applying tension.

In a state in which the tension member 70 constructed as described above is coupled to the lower surface of the hollow slab panel 30 as shown in Fig. 10 (a), as shown in Fig. 10 (b) When the knob member 76 is inserted into the horizontal shaft 72 and the knob member 76 is turned clockwise or counterclockwise as shown in FIG. 10 (c), the upper and lower sleeve nuts 73 and 74 of the bolts 71 run in the direction of the male threads of the bolt rod 71 and spread in the longitudinal direction to apply tension to the strand 60. As shown in Fig. 10 (d) ). Accordingly, a plurality of the hollow slab panels 30 can be closely attached to the beam 20 with a tensile force applied to the strand 60 and can be integrated with each other.

1: Stud bolt (attached to the girder) 2: Through hole
3: Nut 4: Fixture 5: Fixing rod
10: Girder
20: beam 21: upper surface flange 22: web
23: insertion opening 24: cutting line
30: hollow slab panel 31: through hole 32: inclined hole
33: Curved tube
40: Support hardware 41: First side 42: Second side
50: Stud bolt (coupled to beam) 60: Strain
70: tension member 71: bolt rod 72: abscissa
73: upper sleeve nut 74: lower sleeve nut 75: nut head
76: Handle member
80: spacer 81: spacer plate 82: mounting plate

Claims (6)

delete A beam 20 comprising a top flange 21 and a web 22 and having a T-shaped cross section and spaced apart in parallel;
A PC (Precast Concrete) panel mounted on a top surface flange (21) of a beam (20) spaced apart at both ends, comprising: a hollow slab panel (30) in which a plurality of through holes (31) crossing both ends of the panel are formed in parallel;
A supporting hardware 40 connected to a first surface 41 fixed to the lower surface of the upper surface flange 21 of the beam 20 and a second surface 42 fixed in contact with the lower surface of the hollow slab panel 30;
A stud bolt (50) coupled along the longitudinal centerline of the upper surface flange (21) of the beam (20);
A straddle 60 installed across the through hole 31 of the hollow slab panel 30 and having both ends fixed to the stud bolts 50;
A tension member (70) coupled along a bottom centerline of the hollow slab panel (30) parallel to the longitudinal centerline of the beam (20); And
A gap plate 81 sandwiched between the hollow slab panels 30 spaced apart with the stud bolts 50 interposed therebetween and a hollow slab panel 30 connected to the upper ends of the spacer plates 81 and spaced apart from each other, A spacer (80) including a mounting plate (82) which is respectively mounted on the base plate / RTI >
A plurality of the hollow slab panels 30 are installed so as to form a continuous surface in the direction of the beam 20 and are spaced apart from each other with the stud bolts 50 interposed therebetween in a direction orthogonal to the beams 20,
The hollow slab panel 30 is formed with an inclined hole 32 in the direction of the tension member 70 in the through hole 31. The straddle 60 is pierced from one side of the hollow slab panel 30, Passes through the hole (31) and the inclined hole (32), passes over the tension member (70), and passes through the inclined hole (32) and the through hole (31) on the other side.
3. The method of claim 2,
The hollow slab panel (30) includes a curved tube (33) embedded in a portion where the through hole (31) and the inclined hole (32) are connected to each other; And a beam-slab panel coupled to the beam-slab panel.
3. The method of claim 2,
The tension member (70) includes a bolt rod (71) having upper and lower male threads formed in different directions;
A transverse shaft 72 protruding from both sides of the bolt rod 71;
An upper sleeve nut (73) coupled to a lower surface of the hollow slab panel (30) and having a female screw groove corresponding to an upper male screw thread of the bolt rod (71);
A lower sleeve nut 74 formed on the inner surface thereof with a female screw groove corresponding to a lower male screw thread of the bolt rod 71; And
A nut head 75 coupled to the lower end of the lower sleeve nut 74 to engage the strand 60; And,
When the bolt rod 71 is turned clockwise or counterclockwise using the transverse shaft 72, the upper and lower sleeve nuts 73 and 74 rotate along the male threads of the bolt rod 71, So as to apply tension to the strand (60).
5. The method of claim 4,
Wherein the nut head (75) passes through the straddle (60) and passes over the beam head (75).
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