KR101517889B1 - Rhamen bridge construction method using prestressed concrete girder of arch-shaped - Google Patents

Abstract

In the present invention, the PSC girder and the hatching protruding wall protruding outward from the fulcrum portion are integrated at the upper portion of the base girder of the fulcrum portion so that the fusing portion is located outside the PSC girder, and the load acting on the upper portion of the PSC girder The present invention relates to a ramen bridge construction method using a non-joint gradient PSC girder to reduce the magnitude of a moment generated in a fulcrum portion.
A preferred embodiment of the present invention comprises the steps of: (a) fabricating a PSC girder in the form of a gradient in which the primary strand is embedded in the longitudinal direction and the overall shape is an arch or a slope on both sides, and straining the primary strand of the PSC girder; (b) reinforcing the head of the steel pipe file by inserting the steel pipe file after digging from the base; (c) forming a foundation girder by placing reinforcing bars and reinforcing bars in the head of the steel pipe pile and placing the concrete so that the upper end of the reinforcing bars is exposed; (d) installing the PSC girder on the upper part of the foundation girder and connecting the ub-reinforced reinforcing bars to both sides of the PSC girder by a reinforcing bar and a coupler constructed inside the PSC girder; (e) installing and reinforcing the formwork from the end of the PSC girder to a point spaced from the end of the PSC girder by a certain distance, and installing a secondary strand from the end of the PSC girder to a point spaced inwardly from the end; (f) simultaneously pouring concrete into the bottom plate, side beam, and fulcrum to simultaneously form the bottom plate, the beam, and the hatching wall; tensing the secondary strand to integrate the hatching wall and the PSC girder; (g) placing reinforcing bars outwardly from the ends of the hatch projecting walls and pouring concrete to form connecting slabs; (h) packaging the top of the PSC girder, the hatching wall and the connecting slab.

Description

{Rhamen bridge construction method using prestressed concrete girder of arch-shaped,

The present invention relates to a ramen bridge construction method using a non-joint gradient type PSC girder, and more particularly, to a construction method of a ramen bridge construction method in which a PSC girder and a hatching protruding wall protruding outward from a fulcrum portion are integrated at an upper portion of a base girder of a fulcrum portion, The PSC girder is installed on the PSC girder, and it is possible to reduce the size of the pendulum caused by the load acting on the PSC girder. .

Generally, in the construction of the ramen bridge, the ramen bridge has the advantage of lowering the bridge height, but the span is short and is not widely used. However, in recent years, steel composite bridges using preflex beams have been developed to realize low-strength, long-span rayman bridges. However, there is a problem in that the size of the bridge can not be reduced at the lower portion of the upper flange of the girder made of rayman- there was. In order to solve this problem, a steel material is attached to the lower portion of the girder so as to reduce the size of the moment, or a pair of fixing holes are provided at the lower portion of the girder and thereafter the steel rods are connected. So that it acts only on the erosion or the fulcrum portion, so that it acts only on the erosion or the fulcrum portion, so that the bearing capacity of the upper structure of the bridge can not be maximized.

As a background of the present invention, there is a patent registration No. 0983861 entitled " Integrated Composite Slab Bridge without Slip, No Slip, and No-Slip Shaft Bonding and Method for Construction thereof "(Patent Document 1). In the background art, as shown in FIG. 8, a plurality of monolingual piles 11 are arranged in one row at a position where the end point portion 24 or the point portion is to be installed along the bank 18 of the point where the bridge is to be installed, A pile head reinforcing steel cage 49 rigidly installed on the installed pillar 11 and a supporting steel bar 65 of the installed pile head reinforcing steel cage 49 or a transverse beam or a pierced A cross bar connecting the installed rolled steel vertical beams to each other, a fixing device 26 installed at both ends of each of the installed rolled steel vertical beams 21, , A PS steel wire positioning spacer (48) for attaching a PS steel wire (23) to the rolled steel vertical beam, and a sheath provided over the spacer; and a sheath (44) ) , A precise fixing device (26) after introducing the prestress into the PS steel wire, grouting installed in the sheath, and reinforced concrete assembly and concrete casting embedded in part and all of the rolled steel vertical beam A shear force is applied to the fixing device 26 and the spacer 48 installed in the transverse direction to interconnect the rolled steel longitudinal beams 21 for additional stress cancellation of the secondary dead load and live load, And a fixing device 26 and a spacer 48 provided on the lateral compensation for interconnecting the rolled steel vertical beams 21 for increasing the load bearing capacity of the installed bridges, (36) provided with a sheath in the spacer and provided in the sheath, a recessed portion provided in a part of the connecting slabs, which is tightened at the end portion of the composite slab, A connecting slab 15 installed by curing concrete so as to fill the hinge 13 and the other end of the meniscus hinge 13 provided at both ends of the composite slab, and a connecting slab 15 connecting the connecting slab and the bridge main body, Characterized in that the connecting slab, the main slab, and the substructure are mutually reinforced unified structures, the bridge being a bridge in which alternation and bridge support are omitted; Type composite slab bridges.

However, the above-mentioned background art has a problem that it is difficult to construct the composite slab and the girder integrally, and it is difficult to manufacture the girder in advance.

Patent Registration No. 0983861 "Integrated Composite Slab Bridges of Non-Alternating, Non-Supporting and Non-Extensible Joints and Their Construction Method"

In order to solve the problems as described above, the present invention provides a hull girder having a hatch protruding wall which is installed on an upper portion of a steel pipe pile at a point of a bridge, The size of the momentum generated in the fulcrum portion due to the load acting on the upper portion of the PSC girder is reduced so that the position of the fulcrum portion at a position other than the fulcrum portion It is possible to support the girder or the bridge superstructure so that the force of the acting load concentrated on the point portion can be dispersed to support the excessive load acting on the bridge while extending the life of the bridge. It is an object of the present invention to provide a ramen bridge construction method using a PSC girder.

(A) a primary strand is embedded in the longitudinal direction and the overall shape is formed as a gradient having an arc or a gradient on both sides, a step is formed on the lower surface of both ends, and a step Studs are formed on the upper surface of the steel plate at constant intervals to manufacture a PSC girder integrally formed with studs and tensioning the primary strand of the PSC girder; (b) reinforcing the head of the steel pipe file by inserting the steel pipe file after digging from the base; (c) forming a foundation girder by placing reinforcing bars and reinforcing bars in the head of the steel pipe pile and placing the concrete so that the upper end of the reinforcing bars is exposed; (d) The PSC girder is placed on the top of the foundation girder. The upper surface of the foundation girder is joined to the steel plate by anchor bolts, and the reinforcing bars are connected to the PSC girder at both ends by reinforcing bars and couplers. Hypothesis; (e) The formwork shall be installed so as to protrude from the end of the PSC girder to a point spaced a certain distance outside the upper part of the foundation girder, with the upper surface extending to have the same gradient as the upper surface of the PSC girder, The second strand is installed so that it is located at the outer end of the formwork and the other end is located at a certain distance from the end of the PSC girder at a certain distance from the end of the PSC girder. ; (f) Concrete is placed simultaneously on the bottom plate, side beam, and fulcrum to simultaneously form the bottom plate, the beam and the hatching wall, and the secondary strand is tensed to unite the hatching wall and the PSC girder, So as to be located at the outer end of the protruding wall (30), thereby reducing the magnitude of the momentum generated in the fulcrum portion by the load acting on the upper portion of the PSC girder; (g) placing reinforcing bars outwardly from the ends of the hatch projecting walls and pouring concrete to form connecting slabs; and (h) packaging the upper portion of the PSC girder, the hatching protruding wall, and the connecting slab. The present invention is to provide a ramen bridge construction method using a PSC girder without a joint gradient.

Also, in step (d), a pad made of a synthetic resin is sandwiched between the lower surface of the steel plate of the PSC girder and the base girder.

Also, in the step (e), it is desired to provide a method of raymen bridge construction using a joint-free gradient PSC girder characterized in that one end of the reinforcing bars is arranged so as to intersect the reinforcing bars of the base girders.

In the step (a), the PSC girder is formed with a fixing block in which a sheath pipe is protruded to the side, and a secondary strand is disposed in the fixing block in the step (e) Type PSC girder is proposed.

In the step (e), a third strand is connected so that a third strand is connected to the end of the second strand, and the outer end of the third strand is positioned at the end of the second strand. And in the step (f), the third strand is further tensioned after the formation of the hatching protruding wall, thereby providing a ramen bridge construction method using a no-joint gradient PSC girder.

In the ramen bridge construction method using the non-joint gradient type PSC girder of the present invention, a foundation girder is installed on the upper part of the steel pipe pile at the point of the bridge, a hatching protruding wall is installed so as to project the PSC girder on the upper part of the foundation girder, The PSC girder and the hatching protruding wall are integrated with each other through the tangential tension of the fuselage so that the position of the fusing portion is located at the outer end of the hatching protruding wall so that the magnitude of the pendulum generated at the fulcrum portion due to the load acting on the PSC girder The bridge can be supported at the position other than the fulcrum, and the load of the bridge acting on the fulcrum can be dispersed so as to support the excessive load acting on the bridge while extending the life of the bridge There is a very useful effect.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a construction sequence of a ramen bridge construction method using a joint-free gradient PSC girder of the present invention in the order of construction.
2 is a perspective view of the PSC girder 10 of the present invention.
3 is a perspective view of the foundation girder 20 of the present invention.
4 is a perspective view showing a state in which the PSC girder 10 is installed on the base girder 20 of the present invention.
5 is a perspective view showing a state in which the secondary strand 32 of the present invention is disposed.
6 is an enlarged view of a part of a fulcrum showing an embodiment in which a tertiary strand 11a is installed in the present invention.
7 is a side view showing an embodiment of a bridge constructed by a ramen bridge construction method using a non-joint gradient PSC girder of the present invention.
FIG. 8 is a view showing that a conventional composite slab bridge is constructed by using a rolled steel vertical beam installed in one row with a small footprint.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

 Hereinafter, the technical structure of the present invention will be described in detail with reference to the preferred embodiments.

The present invention provides a ramen bridge construction method using a non-joint gradient type PSC girder, in which a foundation girder is installed on the upper part of a steel pipe pile at a point of a bridge, a PSC girder and a hatching protruding wall are installed on the foundation girder, The PSC girder is provided with a fixing protruding wall protruding outwardly from the PSC girder so as to be positioned outside the PSC girder so that the magnitude of the residual stress generated in the fulcrum portion is reduced by the load acting on the upper portion of the PSC girder, It is possible to support the girder of the bridge even in the position so as to disperse the magnitude of the moment acting excessively on the fulcrum portion so as to extend the durability of the bridge,

Hereinafter, a method of constructing a ramen bridge using a joint-free gradient PSC girder according to the present invention will be described in detail with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a construction sequence of a ramen bridge construction method using a joint-free gradient PSC girder of the present invention in the order of construction.

First, as shown in FIG. 1A, a PSC girder 10 is manufactured and a prestress is introduced (a).

In order to minimize the bridge height to the bridge between the long span and the bridge of the bridge, it is necessary to use the PSC girder with the lower bridge structure and to introduce the prestress so that the stress and deformation of the external force can be canceled and recovered.

The PSC girder 10 is formed in a graded shape in which the primary strand 11 is embedded in the longitudinal direction and the overall shape is an arch or a gradient on both sides.

The PSC girder 10 may be formed into a shape having an entire shape in an arch shape or a shape in which both end portions have a gradient so that a gradient is formed at only a predetermined angle at both ends. As described above, by using the PSC girder 10 manufactured in the form of an arch or a gradient, it is possible to minimize the upper self weight and to facilitate the stress transmission, thereby ensuring economical efficiency and structural efficiency at the same time.

The PSC girder 10 is constructed such that the primary strand 11 is arranged in the longitudinal direction for maintenance for the purpose of increasing the rigidity and offsetting the external force so that the primary strand 11 is tensed after the PSC girder 10 is manufactured, .

2 is a perspective view of the PSC girder 10 of the present invention.

As shown in FIG. 2, the PSC girder 10 may have a step 14 formed on a lower surface of both ends thereof, and a steel plate 15 may be formed on the step 14. The steel plate 15 is configured to facilitate engagement with a base girder 20 to be described later. The step 14 is formed to have a thickness equal to the thickness of the steel plate 15. [

The steel plate 15 is formed to penetrate the PSC girder 10 so as to protrude from both sides in the width direction of the PSC girder 10 so that the protruded portion of the steel plate 15 is coupled with the base girder 20 and the anchor bolt 25 Thereby making it easy to engage with the base girder 20. The steel plate 15 and the PSC girder 10 are integrally formed with the PSC girder 10 so that the stud 15a is formed at the upper surface of the steel plate 15 at regular intervals.

The PSC girder 10 is provided with a second secondary strand 32a so as to protrude from the side surface and a fixing block 17 in which the sheath pipe is embedded so that the end of the secondary strand 32a can be fixed So that the fixing of the end portion can be facilitated when the secondary strand 32a is disposed.

 Thereafter, the steel tube pile 21 is inserted after the base is destroyed, and the head of the steel tube pile 21 is reinforced (b).

As shown in Fig. 1B, the portion of the PSC girder 10 on which the fulcrum portion is provided is dismantled, and the steel pipe file 21 is inserted.

The foundation is formed by the site-stiffened steel pipe pile 21 at the point of time of the bridge and the foundation girder 20 described later is formed on the upper side of the steel pipe pile 21. [

Thereafter, concrete is inserted into the head of the inserted steel pipe 21 to form the foundation girder 20 (c).

 The base girder 20 is formed at the upper end of the inserted steel pipe 21 and corresponds to the point where the end of the PSC girder 10 is seated and installed.

As shown in FIG. 1C, a general reinforcing bar is laid on the head of the steel pipe 21 inserted in order to form the base girder 20, and concrete is laid on the base girder 20 to form the base girder 20. In addition, The reinforcing bars 22 are disposed so that the openings face downward, and the concrete is laid so that the upper portion is exposed after the concrete is laid.

3 is a perspective view of the foundation girder 20 of the present invention. As shown in FIG. 3, when the concrete is laid to form the foundation girder 20, the upper end of the C-shaped reinforcing bar 22 is exposed on the upper surface of the foundation girder 20.

After the base girder 20 is formed as described above, the PSC girder 10 is placed on the upper portion of the foundation girder 20 so that the PSC girder 10 is installed (d).

The reinforcing bars 12 are provided at the ends of the PSC girder 10 so as to be connected to the ends of the PSC girder 10 at the ends of the PSC girder 10, And the coupler 13 is connected to the reinforcing bars formed therein.

4 is a perspective view showing a state in which the PSC girder 10 is installed on the base girder 20 of the present invention. As shown in FIG. 4, the C-shaped reinforcing bars 12 are overlapped with the C-shaped reinforcing bars 22 exposed on the upper surface of the foundation girder 20. As shown in FIG. In addition, each of the C-shaped reinforcing bars 12 and the C-shaped reinforcing bars 22 may be alternately arranged so as to be alternately arranged.

A pad 16 formed of synthetic resin may be interposed between the lower surface of the steel plate 15 and the base girder 10 when the PSC girder 10 is seated on the upper portion of the foundation girder 20. [

Thereafter, the reinforcing bars 31 are laid to form the laterally projecting wall 30, and the secondary strand 32 is installed (e).

1E, a laterally described hatching wall 30 is formed to protrude from the end of the PSC girder 10 to a position spaced apart from the upper portion of the base girder 20 by a predetermined distance. For this purpose, the PSC girder 10 10, the upper surface of the PSC girder 10 is extended so as to have the same gradient as the upper surface of the PSC girder 10 and the lower surface thereof has a constant slope A mold is provided so as to be formed into a tapered shape, and a reinforcing bar 31 is disposed.

The mold and the reinforcing bar are installed to place the hatching protruding wall 30, and at the same time, although not shown, the mold for forming the bottom plate and the beam is assembled and the reinforcing bars are installed.

When the molding of the formwork and the reinforcing bars 31 is completed to form a hitting and protruding wall 30 to be described later, a secondary strand 32 is provided at an upper portion where the hatching wall 30 is to be formed.

The secondary strand 32 may be provided by embedding the sheath tube and installing the secondary strand 32 on the sheath tube or by using a non-stiffened strand.

5 is a perspective view showing a state in which the secondary strand 32 of the present invention is disposed. As shown in Figs. 1E and 5, one end of the secondary strand 32 is located at the outer end of the hatch projecting wall 30, which will be described later, and the other end is spaced a certain distance inward from the end of the PSC girder 10 Position.

When the fixing block 17 is formed on the PSC girder 10, the secondary strand 32a is also provided on the sheath pipe constructed inside the fixing block 17. [

Then, concrete is simultaneously placed in the bottom plate, the side beam and the fulcrum portion to simultaneously form the bottom plate, the beam, and the hatching and protruding wall 30. The tentative projecting wall 30 and the PSC girder 30, (F).

1F, when the hatching protruding wall 30 is formed, one end of the secondary strand 32 on the outer side of the hatching protruding wall 30, that is, on the side opposite to the side adjacent to the PSC girder 10 And the PSC girder 10 and the hatching protruding wall 30 are integrated by tightening and fixing the other end located at a position spaced a certain distance inward from the end of the PSC girder 10.

The hatch projecting wall 30 is formed in a saw-tooth shape in which the upper surface extends to have the same gradient as the upper surface of the PSC girder 10 and the lower surface has a constant inclination. That is, the PSC girder 10 is formed so as to protrude outward from the end of the PSC girder 10, which is mounted on the upper end of the outer base girder 20 at the base girder 20 of the fulcrum portion.

6 is an enlarged view of a part of a fulcrum showing an embodiment in which a tertiary strand 11a is installed in the present invention.

As shown in Fig. 6, in step (e), one of the secondary strands 32 is selected and joined so that a separate tertiary strand 11a is connected to the end of the secondary strand 32, And the third strand 11a is further tensioned after the formation of the hatching protruding wall 30 in step (f), so that the third strand 11a is located at the end where the end of the second strand 32 is located. .

The hitting protruding wall 30 thus formed tensions the secondary strand 32 or strains the secondary strand 32 and the tertiary strand 11a to form the hatch projecting wall 30 and the PSC girder 10 The position of the fusing portion located at the end portion of the PSC girder 10 is moved from the fulcrum portion to the outside of the hatching protruding wall 30 so as to be located at the fulcrum portion by the load acting on the upper portion of the PSC girder So that the magnitude of the generated momentum can be reduced.

Thereafter, the reinforcing bars are installed outwardly from the end of the hatching protruding wall 30, and concrete is poured to form the connecting slab 40 (FIG.

1G, a meninge hinge 41 or the like is previously disposed in the joint between the knocking protruding wall 30 and the connecting slab 40 in step (e) of arranging the knocking protruding wall 30 to form the knocking protruding wall 30 So that the hatching protruding wall 30 and the connecting slab 40 can be integrated.

Then, as shown in FIG. 1 (h), the PSC girder 10, the hatching protruding wall 30 and the upper portion of the connecting slab 40 are packed and completed (h).

7 is a side view showing an embodiment of a bridge constructed by a ramen bridge construction method using a non-joint gradient PSC girder of the present invention.

7A and 7B, it is possible to form the foundation girder 20 and constitute the hatch projecting wall 30 at the position where the alternation is to be formed irrespective of the presence or absence of the bridge pillar P, The shape of the arc tube 10 may be a gradient type having an arch or a downward angle with both end portions being constant.

In the ramen bridge construction method using the non-joint gradient PSC girder of the present invention having the above-described steps, a foundation girder is installed on the upper part of the steel pipe pile at the point of the bridge, the PSC girder is mounted on the foundation girder, The PSC girder and the hatching protruding wall are integrated so that the position of the fixing unit is located at the outer end of the hatching protruding wall so that the size of the pendulum generated in the fulcrum portion due to the load acting on the PSC girder is The bridge can be supported at a position other than the fulcrum portion to disperse the force of the acting load concentrated on the fulcrum portion so as to support the excessive load acting on the bridge, There is a very useful effect that can be extended.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: PSC girder
11: Primary strand
11a: Third strand
11b: Coupler
12: C-shaped rebar
13: Coupler
14: Step
15: Steel sheet
15a: Stud
16: Pad
17: Settlement block
20: foundation girder
21: Steel pipe file
22: C-shaped rebar
25: Anchor bolt
30:
31: Rebar
32, 32a: Second strand
40: connecting slab

Claims (5)

(a) a primary strand 11 is embedded in the longitudinal direction and the overall shape is a gradient having an arc or a gradient on both sides, a step 14 is formed on the lower surface of both ends, and a step 14 The PSC girder 10 is integrally formed by embedding the studs 15a so that the studs 15a are formed on the upper surface of the steel plate 15 at predetermined intervals, Tensioning the primary strand (11) of the girder (10);
(b) reinforcing the head portion of the steel pipe pile (21) by inserting the steel pipe pile (21) after digging from the base;
(c) forming a foundation girder 20 by placing reinforcing bars and reinforcing the reinforcing bars 22 on the head of the steel pipe 21, and placing the concrete so that the upper ends of the reinforcing bars 22 are exposed;
(d) The PSC girder 10 is seated on the upper part of the foundation girder 20, and the upper surface of the foundation girder 20 is connected to the steel plate 15 with the anchor bolts 25. The U- A PSC girder 10 is installed by coupling at the opposite ends of the PSC girder 10 with the reinforcing bars and the coupler 13 formed in the inside of the PSC girder 10;
(e) a mold is provided so as to protrude from the end of the PSC girder 10 to a position spaced apart from the upper part of the upper portion of the foundation girder 20 by a predetermined distance, the upper surface of the PSC girder 10 being extended to have the same gradient as the upper surface of the PSC girder 10 The PSC girder 10 is installed at one end thereof at the outer end of the formwork and the other end thereof is at the outer end of the PSC girder 10. The reinforcing rods 31 are disposed at the lower end of the PSC girder 10, Providing a second stranded wire (32) at a location spaced a distance inward from an end of the second stranded wire (32);
(f) Concrete is placed simultaneously on the bottom plate, side beam and fulcrum to simultaneously form the bottom plate, the beam and the hatching wall 30, and the secondary stiffening line 32 is tensed and the tentatively projecting wall 30 and the PSC The girder 10 is integrated so that the position of the fixing portion is located at the outer end of the hatching wall 30 so as to reduce the magnitude of the momentum generated in the fulcrum portion due to the load acting on the upper portion of the PSC girder ;
(g) placing reinforcing bars outwardly from the ends of the hatching wall 30 and pouring concrete to form connecting slabs 40;
(h) packaging the PSC girder (10), the hatching wall (30), and the upper portion of the connecting slab (40). The method according to claim 1,
In step (d)
Wherein a pad (16) formed of synthetic resin is sandwiched between a lower surface of the steel plate (15) of the PSC girder (10) and the foundation girder (10). The method according to claim 1,
In the step (e)
Wherein the reinforcing bars (31) are arranged such that one end thereof intersects with the U-shaped reinforcing bars (22) of the foundation girder (20). The method according to any one of claims 1 to 3,
In step (a)
The PSC girder 10 is formed with a fixing block 17 protruding from a side surface thereof and having a sheath tube embedded therein,
In the step (e)
And a second secondary stranded wire (32a) is disposed inside the fixing block (17). The method according to any one of claims 1 to 3,
In the step (e)
So that the outer end of the third strand 11a is located at the end where the end of the second strand 32 is located, so that the third strand 11a is connected to the end of the second strand 32 A third strand of strand 11a is provided,
In step (f)
And the third strand (11a) is further tensioned after forming the hatching protruding wall (30).

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