KR100989586B1 - Girder for rahmen structure, the making method and bridge construction method using girder for rahmen structure - Google Patents

Abstract

PURPOSE: A girder for a rahmen bridge, a manufacturing method thereof, and a bridge construction method using the same are provided to cost-efficiently construct a bridge by optimizing several devices required for reinforcing a corner part. CONSTITUTION: A girder for a rahmen bridge comprises two lower vertical support beams(110), an upper horizontal support beam(120), and end inclination tension devices. The lower vertical support beams are extended from the top of a bridge lower structure. Hinge bearings(140) are installed on the top of the lower vertical support beams. The upper horizontal support beam is placed on the top of the hinge bearings. The end inclination tension devices comprise tendons(130). The tendons are inclinedly installed between the lower vertical support beams.

Description

Ramenized bridge girder, ramenized bridge girder fabrication method and bridge construction method using ramenized bridge girder {GIRDER FOR RAHMEN STRUCTURE

The present invention relates to a method for manufacturing a ramenized bridge girder, a method for producing a ramenized bridge girder, and a bridge construction method using a ramenized bridge girder. More specifically, the ramenized bridge girders that can be installed between the bridge under the bridge structure to be supported simply by the bridge support, the bridge construction between long and long, but also to optimize the reinforcement after the ramenization, The present invention relates to a method for manufacturing a ramenized bridge girder and a bridge construction method using a ramenized bridge girder.

FIG. 1 schematically illustrates a bending moment diagram generated when a fixed load such as a uniformly distributed load 20 is applied to a general ramen bridge 10 by slab self weight and other loads.

The ramen bridge is provided with a slab or ramen bridge girders 12 are installed between the bridge substructure 11, such as a bridge and the upper surface of the bridge substructure.

At this time, between the ramen bridge girders 12 may be formed as a final slab by the slab concrete.

Accordingly, according to the bending moment diagram acting on the ramen bridge 10 by the equal distribution load, in the right angle portion A, the bending parent moments M1- are generated in opposite directions to each other, thereby quantitatively increasing in size. ) Is such that the appropriate reinforcing means (such as haunchi) corresponding to the bending parent moment (M1-) is formed, it can be seen that the bending constant moment (M1 +) is generated in the center of the bridge deck or girder 12 for the bridge bridge.

Accordingly, the ramen bridge 10 is the amount of the bridge substructure and the bridge deck or girder 12 for the bridge in the right angled portion (A) in order to effectively resist the bending moment (M1-) and the bending constant moment (M1 +). The ends are joined in a rigid manner.

The meaning of this rigidity can be said to effectively transfer the bending parent moment acting on the bridge deck or ramen bridge girders structurally to the bridge substructure (shift, pile, etc.).

Therefore, it can be seen that the ramen bridge is very important for the cross section design of the rigid part of the right angle and the load transfer to the lower structure of the bridge. Especially, it is not necessary to install the expansion joint and the bridge support, which is essential to the conventional girder bridge. In small bridges, it is a very economical and efficient bridge type.

Furthermore, in order to increase the span (intersection) of such a ramen bridge, a tension member such as a steel rod (not shown) is installed on the bottom of the slab or ramen bridge girder (12), and the prestress caused by the tension and settlement of the tension bridge is applied to the bridge deck or the ramen bridge girder (12). ) Is also introduced.

The bending moment (tension moment) introduced by this method allows the compression prestress to be introduced into the slab or ramen bridge girders 12 and can reduce the bending parent moment in the bridge undercarriage. Even if the prestress is introduced, it is possible to increase the extension length, that is, the span, in which the slab or ramen bridge girders 12 can be installed.

That is, the bending moment tension moments (M2 +, M2-) acting on the ramen bridge by the introduction of the prestress, the ramen bridge (10) is a bending act by canceling the bending moment (M1-) and the bending constant moment (M1 +) The magnitude of the moment is quantitatively reduced (M3).

However, this method reduces the geometry of the bridge because the tension member is installed on the bottom of the bridge deck or ramen girder (12), and the work of installation and workability will be reduced because the work of installing the tension material is performed on the bottom of the bridge deck or girder (12). In addition, there was a problem that the installation of the tension material on the bridge deck or girder bridge for bridges 12 is not good in appearance.

Accordingly, the present invention is to change the general girder bridge into a ramen structure structure, but it is possible to construct bridges between long and long, but it is possible to make the bridge construction method more economical and efficient by optimizing various devices and means necessary for reinforcing the ridge in the ramen bridge. The technical problem to be solved is to provide a method for manufacturing a ramenized bridge girder, a method for producing a ramenized bridge girder and a bridge construction method using a ramenized bridge girder.

The present invention

Both lower vertical support beams extending upward on the bridge substructure and having hinge supports mounted on the upper surfaces thereof; An upper horizontal support beam mounted to extend further in the transverse direction from the hinge support; And a tension member installed to be inclined downward from an end of the upper horizontal support beam and installed between the lower vertical support beams, and then prestressed by fixation after tension to introduce a bending moment M based on a hinge support to the upper horizontal support beam. It is intended to solve the above technical problem by providing a ramenized bridge girders including;

In addition, the present invention includes a fixing bolt and a nut between the lower vertical support beam and the bottom of the upper horizontal support beam on the side of the hinge support so that the upper horizontal support beam is not separated from the hinge support by the pre-stress introduced by the end slope tension device. The technical problem is solved by providing a ramenized bridge girder formed with a departure prevention device.

In addition, the present invention is to solve the above technical problem as the lower vertical support beam and the upper horizontal support beam is a ramenized bridge girders that can extend the applicability, including the reinforced concrete beam or steel beam.

In addition, the present invention extends upward to the bridge lower structure and to form a lower vertical support beam so that the hinge support is mounted on the upper surface,

Forming an upper horizontal support beam so as to extend further in the transverse direction from the hinge support;

Inclined downward from the end of the upper horizontal support beam is installed between the lower support beam or the bridge lower structure and then prestress is introduced by the fixing after the tension, the end inclination so that the bending moment (M) is introduced to the upper horizontal support beam relative to the hinge support To solve the above technical problem by providing a ramenized bridge girder manufacturing method comprising the step of forming a tension device;

In addition, the lower vertical support beam and the upper horizontal support beam includes a reinforced concrete beam or a steel beam, the lower vertical support on the side of the hinge support so that the upper support girder does not deviate from the hinge support by the introduction of the prestress by the end slope tension device The technical problem is solved by providing a method for manufacturing a girder for a ramenized bridge further comprising a separation prevention device including a fixing bolt and a nut between the beam and the bottom of the upper horizontal support beam.

Also,

Install bridge substructure including shifts,

It is installed to extend upward to the bridge lower structure, and the hinge support is installed on the upper surface and both lower vertical support beams are provided with a fixed end on the lower outer surface,

The length is formed so as to extend further in the transverse direction from the hinge support, and installed to support the upper horizontal support beam having a fixing end formed at both ends on the hinge support upper surface,

Installing a separation prevention device including a fixing bolt and a nut between the lower vertical support beam and the upper horizontal support beam bottom surface around the hinge support,

After the upper end of the tension member is fixed to the fixing end and disposed to be inclined downward so that the lower end is fixed to the fixed end formed in the lower vertical support beam or the bridge lower structure, the bending moment is tensioned and fixed through the fixing end. The technical problem is solved by providing a bridge construction method using a ramenized bridge girder, comprising the step of being introduced to the upper horizontal support beam.

In another aspect, the present invention is to solve the above technical problem by providing a bridge construction method using a ramenized bridge girders, the lower vertical support beam and the upper horizontal support beam including a reinforced concrete beam or a steel beam.

Accordingly, the ramenized bridges according to the present invention can realize the advantages of the ramenized bridges while still using the form of general bridges, thereby making it more economical and efficient to manufacture and construct bridges.

In addition, it is simple to install and can be applied to any type of girder because the bridge can be ramenized by the tension material work type, so it can be applied to steel girder as well as reinforced concrete girder, so it is very useful bridge construction method Provision is possible.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

1 is a schematic diagram showing the loading action of the conventional ramen bridge and the bending moment, the loading action schematic diagram of the conventional ramen bridge by the introduction of the tension force,
Figure 2 is a schematic diagram of the load action and bending moment of the ramenized bridge according to the present invention, the load action schematic diagram of the conventional ramen bridge by the introduction of tension force,
3 and 3b is a partial perspective view of the ramenized girders according to the present invention,
4A, 4B and 4C are construction flowcharts of the ramenized bridges according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

<Ramenization method of bridge according to the present invention>

Figure 2 shows a ramenized bridge 100 and a working load schematic diagram according to the present invention.

That is, in the ramenized bridge 100 according to the present invention, it can be seen that the lower vertical support beams 110 are spaced apart from each other in the lateral direction as shown in FIG.

The upper horizontal support beam 120 is installed on the upper surface of the lower vertical support beam 110,

The upper horizontal support beam 120 and the lower vertical support beam 110 can be seen that the connection state is formed in the hinge connection state by the hinge support 140.

Accordingly, when the upper horizontal support beam 120 is supported by the lower vertical support beam 110 and installed stably, the bending occurs when an equal distribution load acts on the upper horizontal support beam 120 such as a fixed load. Looking at the moment,

The bending moment does not occur at point A, which is one end of the upper left horizontal support beam, and the bending parent moment (M-) increases to the point B, which is the hinge connection part (the hinge support installation part), in an upward straight line shape. ,

As the bending parent moment decreases from the point B to the right side, it can be seen that the bending constant moment M + is generated after passing the inflection point C (the bending parent moment is changed to the bending constant moment).

Accordingly, the bending moment from the inflection point C to the right inflection point D increases and decreases in a parabolic form,

From the inflection point D, the bending parent moment (M-) increases again to the hinge connection E,

From the point E of the hinge connection portion to the right, the bending parent moment gradually decreases, and it can be seen that the bending parent moment does not occur again at the point F of the other end of the upper horizontal supporting beam.

Therefore, if the bending parent moment and bending moment (M1 +, M1-) can be reduced, more long-term ramenized bridge construction can be achieved.

At both ends of the upper horizontal support beam 120 is inclined downward, for example, the tension member 130 is installed in the lower vertical support beam, and the compressive prestress is introduced into the tension member.

Accordingly, it can be seen that the compression prestress by the tension member 130 generates the tension moment M2 in the upper horizontal support beam stagnation.

When the bending moment action by the uniform load action and the tension moment action by the tension member are combined,

It can be seen that the overall size of the bending moment due to the uniformly distributed load action is considerably reduced.

That is, in the present invention, the upper horizontal support beam 120 is installed in a hinged state to the lower vertical support beam 110, and is inclined downward from both ends of the upper horizontal support beam to be inclined between the lower vertical support beams 130. It can be seen that the bending moment acting on the bridge can be reduced by

In the present invention, the ramenization method

The upper horizontal support beam extends in the lateral direction more than the lower vertical support beam,

The upper horizontal support beam is supported by the lower vertical support beam by the hinge support,

Compression prestress is introduced at both ends of the upper horizontal support beam by a tension member installed downward to the lower vertical support beam.

Finally, it can be seen that it is possible to reduce the magnitude of the bending moment generated in the upper horizontal support beam as a whole.

<Ramenized bridge girder and its manufacturing method according to the present invention>

The ramenization method of the bridge discussed above shows the actual production of the girder girders.

That is, FIG. 3A may be particularly referred to as using a girder made of steel, and FIG. 3B may be particularly referred to as using a CS girder.

First, it looks at the ramenization bridge girder and its manufacturing method according to Figure 3a.

That is, the bridge girders include a lower vertical support beam 110, an upper horizontal support beam 120, a tension member 130, and a hinge support 140 formed to be curved upward, which are largely made of steel beams (such as an I-beam). do.

The lower vertical support beam 110 is manufactured by cutting steel beams having an I-shaped cross section by both flanges 111 and 112 and the abdomen 113 to have a predetermined length, and as described later, the bridge lower structure 400. ) It is a member installed vertically on the upper surface.

A fixed end 200 is formed on the lower outer surface of the lower vertical support beam 110, which may be called to allow the other end of the tension member 130 to be described below to be fixedly connected.

The fixed end 200 is tensioned by the fixing plate 220 and the fixing nut 230 by the other end of the tension member 130 is installed inclined as shown in Figure 3a through the flange 111 to penetrate the fixing plate 210 The other end of the 130 is fixed.

In addition, the lower support plate 114 in the form of a horizontal plate is formed on the lower surface of the bridge lower structure 400 to be described later to be fixed to the lower vertical support beam 110, the lower support plate 114 is an anchor ( 115) to be fixed to the upper surface of the bridge lower structure (400).

In addition, the upper support plate 116 of the horizontal plate-shaped semi-circular hinged support 140 is bent on the upper surface to be fixed by the acupressure reinforcing plate 117.

The upper horizontal support beam 120 is installed to support the bottom surface of the hinge support 140 of the lower vertical support beam 110.

It can be seen that the upper horizontal support beam 120 is also made of steel beams (eg, I-beam) and is formed of both flanges 121 and 122 and the abdomen 123.

At this time, the upper horizontal support beam 120 has a length that extends further in the horizontal direction based on the hinge support 140 of the lower vertical support beam 110 in determining the horizontal extension length.

Accordingly, the upper horizontal support beam 120 is supported by the hinge support 140 so that both ends are positioned at the side of the hinge support 140.

At this time, both ends of the upper horizontal support beam 120 is formed with a fixing end 300 for fixing the tension member after the tension.

The fixing end 300 is a fixing plate 320 and the fixing nut 330 by passing through the fixing plate 310 formed on the upper surface of the upper flange of the tension member 130 is installed inclined as shown in Figure 3a through the flange 122 By the upper end of the tension member 130 is to be fixed after the tension.

In addition, above the hinge support 140, a plurality of vertical reinforcement for resisting local acupressure is installed on the hinge support.

The upper horizontal support beam 120 can be seen that the lower vertical support beam 110 is installed by the hinge support 140, in this state may be an unstable support state.

Accordingly, the present invention uses the separation prevention device 500 around the hinge support 140 to prevent the upper horizontal support beam 120 from being separated from each other during the tension work by the tension member after the lower vertical support beam 110.

Accordingly, through holes are formed in the upper support plate 116 installed on the upper surface of the lower vertical support beam 110, and through holes are formed in the flange 122 of the upper horizontal support beam 120 to be fastened to both through holes. The fixing bolt 510 is installed by the fixing nut 520 to install the separation preventing apparatus 500.

Next, the tension member 130 is installed. The tension member 130 may use a steel bar, or may use a stranded wire, but since it is exposed to the outside, it is preferable to use an unattached stranded wire, but is not limited thereto.

In the present invention will be described based on the use of steel bar. Therefore, the lower end and the upper end of the tension member 130 is processed to the screw portion, and the lower end is to be fixed by the fixing nut 230 to the fixing plate 220 through the fixing plate 210 of the lower vertical support beam 110. ,

The upper end portion is penetrated through the fixing plate 310 formed at both ends of the upper horizontal support beam 120 to be fixed after being fixed to the fixing plate 320 by the fixing nut 330.

Accordingly, the ramenized bridge girder according to the present invention is manufactured by assembling the lower vertical support beam 110, the upper horizontal support beam 120, and the hinge support 140 to each other, and installed in the bridge lower structure in the field. After it can be seen that the tension member 130 is installed in such a way as to settle after tension.

In addition, the fixed end 200, the fixing end 300 and the tension member 130 will be referred to as an inclined tension device in particular in the present invention.

Next, look at the bridge girders according to Figure 3b and its manufacturing method. Ramenized bridge girders of the present invention by Figure 3b is the lower vertical support beam 110, the hinge support 140 and the tension member 130 is the same, and the fixed end 200 and the fixing end 300 is also different not.

That is, the difference is that the conventional PS beam as the upper horizontal support beam 120, the PS beam is to install the PS strands in the reinforced concrete beam, the prestress is introduced in the longitudinal direction.

Accordingly, the fixing end 300 of the PS beam has a through hole formed as shown in FIG. 3B, and the upper end of the tension member 130 is fixed after being tensioned by the fixing plate 320 through the block-out block groove 340. The nut 330 is to be fixed.

<Construction Method of Ramenized Bridge Girder According to the Present Invention>

Looking at the construction method of the ramenized bridge girder step by step according to the present invention as follows, the lower vertical support beam 110, the upper horizontal support beam 120, the tension material ( 130 and the hinge support 140 are as described in detail above, so a detailed description thereof will be omitted.

First, as shown in FIG. 4a, the bridge substructure 400 including the shift is installed.

The bridge substructure 400 may be alternate in that it is a ramenized bridge, and the bridge substructure by the pile does not matter.

Next, both lower vertical support beams 110 are installed to extend upward in the bridge lower structure 400 and the hinge support 140 is installed on the upper surface. That is, since the lower support plate 114 is formed on the lower surface of the lower vertical support beam 110, the lower vertical support beam 110 is bridged using the anchor 115 to the lower support plate 114. It is fixed to the upper surface of the lower structure 400 vertically.

Furthermore, as described above, since the fixing end 200 is installed on the lower outer surface of the lower vertical support beam 110, the lower end of the tension member 130 may be fixed as described below.

Next, as shown in FIGS. 4B and 4C, the length is formed to further extend in the lateral direction from the hinge support 140, and the upper horizontal support beam 120 having the fixing end 300 formed at the end is hinged 140. It is installed to be supported on the upper surface.

This is installed so as to be supported by the hinge support 140 of the lower vertical support beam 110 by lifting the upper horizontal support beam 120 using a lifting device such as a crane in the field.

Accordingly, it can be seen that the upper horizontal support beam 120 is hinged to the lower vertical support beam 110 by the hinge support 140.

However, since the hinge connection state may be somewhat unstable, the separation preventing device 500 including the fixing bolt and the nut is installed between the bottom of the lower vertical support beam and the upper horizontal support beam around the hinge support.

This separation prevention device 500 does not interfere with the hinge connection of the upper horizontal support beam 120 and the lower vertical support beam 110, but only to stabilize the installation state.

Next, a fixed end formed at the lower vertical support beam 110 with the lower end formed with the upper end having the threaded portion mounted on the fixing end 300 installed at both ends of the upper horizontal support beam 120 and inclined downward so as to form the lower vertical support beam 110. It is to be fixed to (200).

That is, in the fixed end, the lower portion of the tension member is fixed by the fixing nut, and in the fixing end, the tension member is fixed by being fastened by the fixing nut.

Accordingly, it can be seen that the bending moment is introduced into the upper horizontal support beam 120 through the tension member, the fixing end, and the fixed end so that the final bridge can be ramenized.

Although not shown, the upper horizontal support beam is horizontally spaced apart in the bridge substructure to form the slab by slab formwork and slab concrete for the construction of the slab, and this work is a common operation. Therefore, it is possible to construct according to the site conditions and use deck plates for bridges.

100: Ramenization Bridge
110: lower vertical support beam
114: lower support plate
120: upper horizontal support beam
130: tension material
140: hinge support
200: fixed end
300: settlement
400: lower support structure
500: Departure prevention device

Claims (7)

Both lower vertical support beams extending upward on the bridge substructure and having hinge supports mounted on the upper surfaces thereof;
An upper horizontal support beam mounted to extend further in the transverse direction from the hinge support; And
An end portion including a tension member installed to be inclined downward from the end of the upper horizontal support beam and installed between the lower vertical support beams, and then prestressed by fixation after tension to introduce a bending moment based on a hinge support to the upper horizontal support beam. Ramenized bridge girder comprising a; The method of claim 1,
An anti-separation device further includes a fixing bolt and a nut between the lower vertical support beam and the lower surface of the upper horizontal support beam on the side of the hinge support such that the upper horizontal support beam is not separated from the hinge support by the introduction of the prestress by the end slope tension device. Ramenized bridge girders, characterized in that formed. 3. The method according to claim 1 or 2,
And the lower vertical support beam and the upper horizontal support beam comprise reinforced concrete beams or steel beams. A lower vertical support beam is formed to extend upward to the bridge undercarriage so that the hinge support is mounted on the upper surface.
Forming an upper horizontal support beam so as to extend further in the transverse direction from the hinge support;
Inclined downward from the end of the upper horizontal support beam is installed between the lower support beam or the bridge lower structure and then prestress is introduced by the fixing after the tension, the end inclination so that the bending moment (M) is introduced to the upper horizontal support beam relative to the hinge support Ramenized bridge girder manufacturing method comprising the step of forming a tension device. 5. The lower vertical support beam and the upper horizontal support beam of claim 4, wherein the lower vertical support beams include a reinforced concrete beam or a steel beam, and are hinged so that the upper support girder does not deviate from the hinge support by introduction of prestress by the end slope tension device. The method of manufacturing a ramenized bridge girder, characterized in that for forming a separation preventing device further comprising a fixing bolt and a nut between the lower vertical support beam and the upper horizontal support beam bottom. Install bridge substructure including shifts,
It is installed to extend upward to the bridge lower structure, and the hinge support is installed on the upper surface and both lower vertical support beams are provided with a fixed end on the lower outer surface,
The length is formed so as to extend further in the transverse direction from the hinge support, and installed to support the upper horizontal support beam having a fixing end formed at both ends on the hinge support upper surface,
Installing a separation prevention device including a fixing bolt and a nut between the lower vertical support beam and the upper horizontal support beam bottom surface around the hinge support,
After the upper end of the tension member is fixed to the fixing end and disposed to be inclined downward so that the lower end is fixed to the fixed end formed in the lower vertical support beam or the bridge lower structure, the bending moment is tensioned and fixed through the fixing end. Bridge construction method using a ramenized bridge girders comprising the step of being introduced to the upper horizontal support beam. 7. The bridge construction method according to claim 6, wherein the lower vertical support beam and the upper horizontal support beam comprise a reinforced concrete beam or a steel beam.

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