KR102546964B1 - Bridge cantilever construction method - Google Patents

Abstract

The present invention is a method for constructing cantilevers on both sides of a bridge, comprising the steps of: a) installing girders 1; B) Mounting the cantilever deck 100 integrally provided with the fixture 200 on the outer upper part of the outermost girder 1 without installing a support under the cantilever deck 100; c) fixing the cantilever deck 100 to the outermost girder 1 using the fixture 200; D) It relates to a cantilever construction method of a bridge including the step of placing cast-in-place concrete on top of the girder 1 and the cantilever deck 100.

Description

Bridge cantilever construction method {Bridge cantilever construction method}

The present invention relates to a method for constructing cantilevers on both sides of a bridge.

More specifically, it relates to a cantilever construction method of a bridge that does not require a support, has excellent bending stiffness, and can prevent deflection of the free end of the cantilever by using a cantilever deck integrally provided with a fixture to mount and fix it.

A bridge is a civil structure that connects spaces and provides passages for people, vehicles, trains, water resources, and cargo to move. Bridges are completed by installing girders on substructures such as abutments and piers, and installing bottom plates, cantilevers, and slabs on top of the girders.

Recently, in order to improve the productivity and quality of bridge construction, a bridge construction method that manufactures members in a factory and assembles them at the construction site or minimizes on-site work is widely used.

The cantilever of the bridge also uses a lot of decks made of precast, but in order to fix the precast deck to the girder, a large-scale support that can temporarily support the deck is needed.

However, this construction method using supports requires a lot of manpower and cost for manufacturing, transporting, assembling, dismantling, and demolition of supports, and there is a problem in that construction does not proceed quickly.

In addition, conventionally, in order to integrally fix the cantilever deck to the girder, an excessively complex coupling structure is taken, resulting in poor economic efficiency and time consuming construction.

Therefore, it was necessary to develop a cantilever construction method for a bridge in which the combination structure between the deck and the girder is simple, does not require a support for supporting the deck, is easy to construct, and can shorten the construction period.

Registered Patent Publication No. 10-2487850

In order to improve the above problems of the prior art, an object of the present invention is to provide a cantilever construction method of a bridge that can be easily and quickly constructed without a support for supporting a cantilever deck.

An object of the present invention is to provide a method for constructing a cantilever bridge, which is easy and convenient to construct due to a simple coupling structure between a cantilever deck and a girder.

An object of the present invention is to provide a cantilever construction method for a bridge having a stable support structure and high bending stiffness.

In the present invention, in the method of constructing cantilevers on both sides of a bridge, a) installing a girder (1); B) Mounting the cantilever deck 100 integrally provided with the fixture 200 on the outer upper part of the outermost girder 1 without installing a support under the cantilever deck 100; c) fixing the cantilever deck 100 to the outermost girder 1 using the fixture 200; D) Provides a cantilever construction method of a bridge including the step of placing cast-in-place concrete on the top of the girder 1 and the cantilever deck 100.

The fixture 200 includes a deck fixing unit 210 embedded in the cantilever deck 100; It includes a fixing part 270 having an anchor fixing hole 271 through which the anchor bolt 300 passes, and by fastening the anchor bolt 300 to the fixing part 270, the fixture 200 and the fixture It is characterized in that the cantilever deck 100 provided integrally with the 200 is fixed to the outermost girder 1.

The fixture 200 is provided upwardly from the deck fixing part 210, a connection part 220, a part of which is buried in the cantilever deck 100; a mounting portion 230 provided in a horizontal direction from the connecting portion 220; an inclined portion 240 inclined downward from the holding portion 230; A compression part 250 provided from the inclined part 240 toward the outermost girder 1; It further includes a support part 260 provided downwardly from the compression part 250, and the fixing part 270 is provided toward the inside of the bridge from the support part 260, and the support part 260 and the fixing part 270 ) is fastened to the anchor bolt 300 in a state where the lower surface is spaced apart from the upper surface of the girder 1, so that downward prestress is always applied to the fixing part 270.

The cantilever deck 100 includes a body portion 110 and a holding portion 120, and the ratio of the width w2 of the holding portion 120: the length of the compression portion 250 is 1:0.7 to 1 to be characterized

The cantilever deck 100 further includes a wall portion 130 integrally provided above the end portion of the main body portion 110, and a connecting protrusion 131 is provided at one end of the wall portion 130, and at the top of the other end. A connection groove 132 is provided.

The length (h2) of the support part 260 can be obtained by the formula h2 = (0.85 ~ 0.95) H + t (H: thickness of the cantilever deck 100, t: thickness of the fixture 200).

The length l of the deck fixing part 210 is 16 to 20 times the thickness t of the fixture 200 or 3/10 to 6/10 the width w1 of the main body 110 do.

The deck fixing part 210 and the connection part 220, the connection part 220 and the holding part 230, the compression part 250 and the support part 260, the support part 260 and the fixing part 270 are respectively It is characterized in that the center line forms a right angle.

It is characterized in that the angle (a) between the center line of the crimping part 250 and the horizontal line and the angle (a) between the center line and the horizontal line of the fixing part 270 is 0.5 to 1.5 degrees.

A forced displacement bolt hole 241 is provided in the inclined portion 240, and a forced displacement bolt 280 is fastened to the forced displacement bolt hole 241.

A prestress member 400 is provided on the top of the cantilever deck 100.

The fixture 200 further includes a reinforcing part 211 integrally provided upwardly from the end of the deck anchoring part 210, and a part of the reinforcing part 211 is embedded in the cantilever deck 100, An upper part of the reinforcing part 211 protrudes above the cantilever deck 100, and a fixing rod fixing hole 2111 is provided in the reinforcing part 211 protruding above the cantilever deck 100, and the upper part of the fixing part 270 The fixing bracket 212 provided with the fixing rod fixing hole 2124 is fastened, passing through the fixing rod fixing hole 2111 of the reinforcement part 211 and the fixing rod fixing hole 2124 of the fixing bracket 212. It is characterized in that the fixing rod 213 is fastened to introduce a positive bending moment to the cantilever deck 100.

The fixing bracket 212 includes a fixing part 2121 fastened to contact the fixing part 270; It includes a support part 2122 integrally provided with the fixing part 2121 at right angles, an anchor fixing hole 2123 is provided in the fixing part 2121, and the fixing bar fixing hole is provided in the support part 2122. 2124 is provided.

The cantilever construction method of the bridge of the present invention has the following effects.

First, since the cantilever deck 100 is placed and fixed on the upper part of the girder using the fixture 200, there is no need for a support for supporting the cantilever deck 100, the construction is simple, the construction cost is low, and the construction period is shortened. .

Second, as the anchor bolt 300 is fastened and fixed in a state where the lower surface of the support part 260 and the fixing part 270 of the fixture is spaced apart from the upper surface of the girder 1, downward prestress is always applied to the fixing part 270 Since the cantilever is installed in a falling state, deflection of the cantilever end and cracking of the deck can be prevented in advance.

Third, since the cantilever deck 100 holding part 120 is in complete contact with the upper surface of the girder, and the crimping part 250 always presses the holding part 120, the point condition (boundary condition) of the holding part acts as a fixed end. let it do

Fourth, even if an unexpected manufacturing error occurs when manufacturing the cantilever deck 100 integrated with the fixture 200, the forced displacement bolt 280 can solve the problem caused by the manufacturing error.

Fifth, the prestress member 400 is additionally provided on the upper part of the cantilever deck 100 to reinforce the bending rigidity of the cantilever deck 100 and to reinforce the rigidity against the cast-in-place slab load and additional load.

Sixth, the fixing bar 213 is fastened between the reinforcing part 211 and the fixing bracket 212 to reinforce the rigidity of the cantilever deck 100. , It is possible to introduce a positive bending moment into the cantilever deck 100, thereby reinforcing the bending stiffness of the cantilever deck 100 and reinforcing the stiffness against the cast-in-place slab load, additional load, etc.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a cross-sectional view showing a state in which the cantilever deck of the present invention is placed on the top of the outermost girder, for explaining the configuration of the cantilever deck.
2 is a cross-sectional view in which the cantilever deck of the present invention is mounted and fixed on the top of the outermost girder by a fixture.
3 is a cross-sectional view of the cantilever deck of the present invention in which the fixture is integrally provided.
4 is a plan view of the cantilever deck of the present invention in which the fixture is integrally provided.
5 is a perspective view of the cantilever deck of the present invention in which the fixture is integrally provided.
6 is a perspective view of a fixture of the present invention.
7 is a cross-sectional view illustrating the detailed configuration of the fixture of the present invention. The dotted lines drawn between the configurations indicate the boundaries of each configuration.
8 and 9 are cross-sectional views of the fixture of the present invention.
10 is a plan view of the cantilever deck of the present invention in which the fixture is integrally provided.
11 is a cross-sectional view of a cantilever deck equipped with forced displacement bolts.
12 is an AA cross-sectional view of FIG. 10;
13 is a perspective view of a cantilever deck (two fixtures) equipped with prestress members.
14 is a cross-sectional view of a cantilever deck equipped with prestress members.
15 is a plan view of a cantilever deck equipped with a prestress member.
16 is a perspective view of a cantilever deck (one fixture) equipped with a prestress member.
17 and 18 are perspective views showing lifting by connecting two cantilever decks.
19 is a side view showing an embodiment of a fixture having a reinforcement part provided at an end of a deck fixing part and fastening a fixing bracket.
20 is a perspective view showing an embodiment of a fixture provided with a reinforcement part at an end of a deck fixing part and fastening a fixing bracket.
21 is a perspective view of a fixing bracket.
22 is a side view in which a cantilever deck is mounted using a fixture equipped with a reinforcement part and a fixing bracket.
23 is a perspective view in which a cantilever deck is mounted using a fixture equipped with a reinforcement part and a fixing bracket.
24 is a perspective view of an embodiment of the present invention in which a fixture having a reinforcement part and a fixing bracket and a wall part having a connecting protrusion and a connecting groove are applied.
25 is a front view of an embodiment of the present invention in which a fixture having a reinforcement part and a fixing bracket and a wall part having a connection protrusion and a connection groove are applied.

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice with reference to the accompanying drawings. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification. Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a cantilever construction method of a bridge.

The cantilever deck 100, fixture 200, anchor bolt 300, etc. used in the construction method of the present invention will be described first, and then the cantilever construction method will be described.

Based on the bridge axis direction (longitudinal direction of the bridge and girder), the specifications of the cantilever deck will be explained. That is, the size of the body part and the mounting part formed in the longitudinal direction of the girder is expressed as 'length', and the size of the body part and the mounting part formed in the direction orthogonal to the longitudinal direction of the girder is expressed as 'width'.

In a direction orthogonal to the longitudinal direction of the girder, the outside of the bridge is referred to as the outside of the bridge, and the side toward the center of the bridge is referred to as the inside of the bridge.

The cantilever deck 100 of the present invention includes a body portion 110 and a mounting portion 120, and may further include a wall portion 130.

The cantilever deck 100 can be made of reinforced concrete.

The body portion 110 is formed in a flat plate shape and includes one upper surface 111, one lower surface 112, two front and rear surfaces 113, and one side surface 114.

The upper and lower surfaces 111 and 112 are upper and lower surfaces, respectively, the front and rear surfaces 113 are surfaces facing the bridge axis direction, and the side surface 114 is a surface facing the outside of the bridge in a direction perpendicular to the bridge axis.

It is integrally provided with the mounting portion 120 at the inner end of the bridge of the body portion 110.

The body part 110 is made in the form of a flat plate, but in some cases, protrusions and/or concave parts and/or convex parts may be provided on the upper and lower surfaces, and a shear key may be formed to increase adhesion with the slab concrete. .

The mounting portion 120 is configured to be mounted on the outer upper portion of the outermost girder 1 of the cantilever deck 100, and is integrally provided with the main body portion 110.

The cross-sectional shape and thickness H of the body portion 110 and the mounting portion 120 are preferably provided the same, and the thickness H of the cantilever deck 100 may be 60 to 70 mm.

The mounting portion 120 includes one upper surface 121, one lower surface 122, two front and rear surfaces 123, and one side surface 124.

The upper and lower surfaces 121 and 122 are upper and lower surfaces, respectively, the front and rear surfaces 123 are surfaces facing the bridge axis direction, and the side surface 124 is a surface facing the inside of the bridge in a direction perpendicular to the bridge axis.

For stable mounting and firm fixation of the cantilever deck 100, it is preferable that the side surface 124 of the mounting portion 120 is provided as a vertical surface in a vertical direction.

The wall portion 130 is integrally provided above the end portion of the main body portion 110, and serves as an external formwork when casting-in-place concrete is poured.

In order to make it easy to adjust the height between adjacent cantilever decks 100 when the cantilever deck 100 is mounted without a support, a connecting protrusion 131 is provided on one end of the wall 130, and a connecting groove on the top of the other end ( 132) may be provided.

The fixture 200 of the present invention, which is provided integrally with the cantilever deck 100 and mounts and fixes the cantilever deck 100, includes a deck fixing part 210, a connecting part 220, a mounting part 230, an inclined It includes a part 240, a compression part 250, a support part 260, and a fixing part 270.

When reinforcing bars are placed for manufacturing the cantilever deck 100, the fixture 200 is installed in advance so that the fixture 200 can be firmly fixed in the concrete.

One fixture 200 may be provided per cantilever deck 100, or a plurality of fixtures 200 may be provided on one cantilever deck 100.

The deck fixing part 210, the connection part 220, the holding part 230, the inclined part 240, the compression part 250, the support part 260, and the fixing part 270 are integrally provided in order.

The deck fixing part 210, the connection part 220, the holding part 230, the inclined part 240, the compression part 250, the support part 260, and the fixing part 270 have a constant width and thickness, and a cross section It may be provided in a rectangular plate-like shape and may be made of steel. In addition, a bent plate-like shape or other shapes other than a flat plate-like shape are also possible.

In order to mount and fix the cantilever deck 100 using the fixture 200, anchor bolts 300 are fixed to the top of the outermost girder 1, and nuts 310 are fastened to the anchor bolts 300. By doing so, the cantilever deck 100 integrally provided with the fixture 200 is fixed to the outermost girder 1.

The anchor bolt 300 may be used by being embedded and fixed in advance on the top of the outermost girder 1, or a method of installing it after drilling a hole for installing the anchor bolt on the top of the outermost girder 1 is also possible.

In addition, one anchor bolt 300 may be provided per anchor fixing hole 271 below, or a plurality of anchor fixing holes 271 may be provided, and a plurality of anchor bolts ( 300) may be provided.

It can be used by embedding and fixing it in advance on the top of the outermost girder (1), or it is possible to install it after drilling holes for installing anchor bolts on the top of the outermost girder (1).

The deck anchoring portion 210 is entirely embedded in the cantilever deck 100 in the same direction as the cantilever deck 100 (horizontal direction perpendicular to the vertical line), thereby increasing the adhesion between the deck anchoring portion 210 and the deck. The cantilever deck 100 is supported and the free end of the cantilever deck 100 is prevented from sagging.

In order to increase the adhesion and fixing force between the concrete forming the cantilever deck 100 and the deck anchoring unit 210, a shear key may be provided on the surface of the deck anchoring unit 210.

In order to ensure firm anchoring and rigidity of the fixture 200, it is preferable to position the deck anchoring part 210 to be in contact with the lower part of the main reinforcing bars of the cantilever deck.

The connecting portion 220 is provided upward from the deck anchoring portion 210 .

A portion of the connection portion 220 is buried in the cantilever deck 100, and a portion is exposed to the top of the cantilever deck 100.

The adhesion between concrete and steel is determined by the size of the surface area in contact with each other and the strength of the concrete. Since the compressive strength of the concrete used to manufacture the cantilever deck is constant at 35 to 40 MPa, it is advantageous to increase the surface area per unit length of the fixture to increase the adhesion.

In the present invention, by making the cross-sectional shape of the fixture attached to the concrete of the cantilever deck rectangular, the surface area per unit length is increased by about 1.27 times compared to a circular cross-section with the same cross-sectional area, and as a result, it is possible to exhibit 1.27 times greater bonding strength. let it be

The fixture of the present invention is provided in the form of a flat plate with a square cross section, thereby increasing the attachment strength at the same length (this means that the length of the deck anchorage can be reduced by that much to reduce the manufacturing cost), and is provided in the form of a flat plate, Fastening and fixing work at the top of the girder can be easily performed, and a synergistic effect of facilitating additional bolt fastening at the mounting portion 230 and the inclined portion 240 can be exhibited.

In order to sufficiently secure the surface area of the deck anchoring portion 210 and the adhesive strength and bending stiffness of the deck anchoring portion 210, the length (l) of the deck anchoring portion 210 is 16 of the thickness (t) of the deck anchoring portion 210 ~20 times is preferred.

If it is less than 16 times, the adhesion may be insufficient, and if it exceeds 20 times, the length of the deck fixing part 210 may be more than necessary, which may be uneconomical.

In addition, the length l of the deck anchoring portion 210 may be 3/10 to 6/10 of the width w1 of the body portion 110 .

If the length (l) of the deck fixing part 210 is less than 3/10 of the width (w1) of the body part 110, the adhesive force may be insufficient, and if it exceeds 6/10, it may be uneconomical, Workability may deteriorate.

The deck fixing unit 210 and the connection unit 220 may be provided to form an angle of 90 degrees.

The connection part 220 not only exerts an adhesive force in the section of the connection part 220 bent at 90 degrees from the deck anchorage part 210 and embedded in the concrete, but also resists the pulling force with tensile resistance or compression resistance, thereby providing additional attachment performance can exert

The height of the connection part 220 exposed on the upper surface of the cantilever deck 100 should be at least twice the thickness of the fixture t so that a space of height t or more can be formed under the mounting part 230, so that the fixing bolt 290 described later A space for fastening can be secured.

The thickness t of the fixture 200 may be 8 to 10 mm, and the width of the fixture 200 may be 80 to 120 mm.

The length h1 of the connection part 220 is preferably determined so that the deck anchoring part 210 can contact the lower part of the main reinforcing bars of the cantilever deck and secure the coating thickness of the lower surface of the deck anchoring part 210.

When the coating thickness of the lower surface of the deck anchoring portion 210 is set to t (the coating thickness of the main reinforcing bar is 2t), the length h1 of the connection portion 220 is the thickness H of the cantilever deck 100 and the thickness of the fixture It can be the sum of (t) (h1=H+t).

The mounting portion 230 is provided in the horizontal direction from the connection portion 220 at the top of the cantilever deck 100. The deck fixing part 210 and the holding part 230 may be provided in a horizontal direction perpendicular to a vertical line, and the connection part 220 may be provided in a vertical direction. It is preferable that the center lines of the deck fixing part 210 and the connecting part 220, and between the connecting part 220 and the mounting part 230 form a right angle.

A bolt hole 231 may be provided in the mounting portion 230, and by fastening the fixing bolt 290 to the bolt hole 231, when lifting to mount the cantilever deck 100 or the cantilever deck 100 ) can be utilized when applying prestress to introduce a positive bending moment.

The inclined portion 240 is inclined downward from the holding portion 230 and acts as an elastic deformation section capable of absorbing deformation energy.

A forced displacement bolt hole 241 may be provided in the inclined portion 240, and manufacturing errors of the cantilever deck 100 may be eliminated by fastening the forced displacement bolt 280 to the forced displacement bolt hole 241. there is.

When manufacturing the cantilever deck 100 integrated with the fixture 200, there is a possibility that the upper surface of the cantilever deck on which the formwork is not installed may not secure the required flatness, and if the required flatness is not secured, the mounting portion 120 An unnecessary space may occur between the upper surface 121 and the lower surface of the compression unit 250, but this problem due to manufacturing errors is solved by generating deformation in the inclined unit 240 by the forced displacement bolt 280.

The forced displacement bolt 280 is fixed to the concrete in a state of pre-fastening to the inclined portion 240 by a nut when manufacturing the cantilever deck.

The compression portion 250 is provided toward the inside of the bridge from the inclined portion 240.

In the case of a pre-installed anchor bolt, when the nut 310 is fastened to the anchor bolt 300, the crimping portion 250 always presses the mounting portion 120 of the cantilever deck 100, so that the cantilever deck 100 ) is supported, and in the case of a post-installation anchor bolt, when the anchor bolt 300 is fixed through the anchor fixing hole 271, the crimping portion 250 always presses the mounting portion 120 of the cantilever deck 100 The state is maintained, and the cantilever deck 100 is supported.

A bolt hole 251 may be provided in the compression part 250, and a bolt may be fastened to the bolt hole 251 according to a purpose.

The support part 260 is provided downwardly from the compression part 250 and is integrally connected to the fixing part 270 .

The support part 260 may be provided to be inclined at a certain angle with the vertical line, and it is preferable that the lower end of the support part 260 is provided with a length enough to be spaced apart from the upper surface of the girder by a certain distance.

This is because when the lower end of the support part 260 is fastened in a state in contact with the upper surface of the girder, the end boundary condition of the cantilever deck mounting part 120 does not become a fixed end and has structurally unfavorable hinge or roller point characteristics.

To this end, it is preferable that a value obtained by subtracting the thickness t of the fixture from the length h2 of the support part 260 is in the range of 0.85H to 0.95H. That is, the length (h2) of the support part 260, h2 = (0.85 ~ 0.95) H + t (H: thickness of the cantilever deck 100, t: thickness of the fixture 200) is preferably set.

The fixing part 270 is provided toward the inside of the bridge from the support part 260.

The fixing part 270 is provided with an anchor fixing hole 271 through which the anchor bolt 300 passes.

In a state where the anchor bolt 300 passes through the anchor fixing hole 271, by fastening the nut 310 to the anchor bolt 300 at the top of the fixing part 270, integral with the fixture 200 The cantilever deck 100 provided with is fixed to the outermost girder 1.

It is preferable that the center lines of the compression part 250 and the support part 260, and between the support part 260 and the fixing part 270 form a right angle.

The point condition (boundary condition) of the cantilever deck 100 mounting part 120 overlapped on the outer upper part of the girder 1 is placed in the boundary condition corresponding to the hinge or roller unless special measures are taken.

In the present invention, the mounting part 120 of the cantilever deck 100 is completely brought into close contact with the upper surface of the girder, and the fixture is fixed to the anchor bolt, so that the fulcrum condition (boundary condition) It acts as a fixed end (horizontal, vertical, rotational displacement does not occur).

In order not to allow rotational displacement of the holding part 120 under the crimping part 250, an external restraining force always acting vertically downward on the crimping part is required. ) occurs during the process of adhering the upper surface.

The point of application of this external restraining force must coincide with the point of action of the reaction force generated at the overlapping portion of the lower surface of the mounting part 120 and the upper surface of the girder 1, or must be located inside the bridge than the point of application of the reaction force so that the deck can be stably supported. there is. That is, the point of application of the reaction force and the point of application of the external restraining force by the crimping portion must be on the same vertical line, or the point of application of the external restraining force must be located inside the bridge. At this time, if the point of application of the external restraining force is inside the bridge than the point of application of the reaction force, it may be more stable in terms of the support structure, but there is a possibility of damage to the end of the mounting part 120 by the external restraining force. , it is desirable that the point of application of the external restraining force is not located too far inside the bridge.

To this end, in the present invention, the application point of the external restraining force and the reaction force are the same, or the application point of the external restraint force is located inside the bridge than the reaction force's application point to prevent damage to the end, the width (w2) of the mounting portion 120 : The ratio of the length of the crimping part 250 is 1: 0.7 to 1.

That is, the width w2 of the holding portion 120 and the length of the crimping portion 250 are made the same, or the length of the crimping portion 250 is 7/10 to 1 of the width w2 of the crimping portion 120. So, while stably supporting the cantilever deck, it is possible to exclude the possibility of damage to the end.

In order to ensure safety against shear destruction of the supporting portion 120, the width w2 of the supporting portion 120 and the length of the crimping portion 250 are greater than or equal to the thickness H of the cantilever deck 100. and it is desirable not to exceed the maximum of 2.0H.

If the width (w2) of the mounting portion 120 and the length of the compression portion 250 are smaller than the thickness (H) of the cantilever deck 100, it may be difficult to achieve stable restraint, and if it exceeds 2.0H, the girder Interference with the shear key provided on the top may occur, resulting in deterioration in workability.

By applying prestress to the fixing part 270, in order to create a state in which external restraining force always acts more effectively, the angle (a) between the center line of the crimping part 250 and the horizontal line and between the center line of the fixing part 270 and the horizontal line The angle (a) of can be 0.5 to 1.5 degrees. At this time, the angle between the support portion 260 and the vertical line may also be 0.5 to 1.5 degrees.

At the top of the fixing part 270, by fastening the nut 310 to the anchor bolt 300, the cantilever deck 100 integrally provided with the fixture 200 is fixed to the top of the outermost girder 1 .

The fixing part 270 may be provided to be inclined upward at a certain angle (a) from the horizontal line, and the nut 310 is fastened while the support part 260 and the fixing part 270 are spaced apart from the upper surface of the girder, After the nut is fastened, downward prestress is introduced into the fixing part 270, so that sagging of the cantilever deck can be prevented in advance.

In addition, since the nut 310 is fastened in a state where the lower end of the support part 260 and the fixing part 270 are spaced apart from the upper surface of the girder, the crimping part 250 after fastening the nut is the mounting part of the cantilever deck 100 ( 120) can be applied with an external restraining force in a state of always pressing, so that the end boundary condition of the cantilever deck 100 mounting portion 120 becomes a fixed end and can be supported more stably.

In order to reinforce the bending rigidity of the cantilever deck 100 and to reinforce against the load of cast-in-place concrete, additional load, etc., a prestress member 400 may be additionally provided on the upper part of the cantilever deck 100.

The prestress member 400 may include a strand 410 and a turnbuckle 420.

Connect the strands 410 to the deck bolts 600 previously fixed to the cantilever deck 100 and the fixing bolts 290 fastened to the bolt holes 231 of the mounting portion 230, and tension with the turnbuckle 420 A positive bending moment can be introduced into the cantilever deck by introducing

In another embodiment of the present invention, a reinforcement part 211 and a fixing bracket 212 may be further included in the fixture 200 .

A reinforcing part 211 is further provided integrally from the end of the fixture 200 and the deck anchoring part 210, and a part of the reinforcing part 211 is embedded in the cantilever deck 100, and the upper part of the reinforcing part 211 A part protrudes above the cantilever deck 100.

It is preferable that a fixing rod fixing hole 2111 is provided in the reinforcing part 211 protruding above the cantilever deck 100, and the deck anchoring part 210 and the reinforcing part 211 form a right angle.

The fixing bracket 212 includes a fixing part 2121 and a support part 2122.

The fixing part 2121 is fastened to come into contact with the fixing part 270, and the support part 2122 is integrally provided with the fixing part 2121 while forming a right angle.

An anchor fixing hole 2123 is provided in the fixing part 2121, and a fixing bar fixing hole 2124 is provided in the support part 2122.

The fixing rod 213 is fastened to pass through the fixing rod fixing hole 2111 of the reinforcing part 211 and the fixing rod fixing hole 2124 of the fixing bracket 212 .

The fixing rod 213 may be fastened by a nut 2131, and it may be fastened to the extent that no tensile force is introduced into the fixing rod 213 so as to exert only a function of holding the reinforcing part 211, preferably. A positive bending moment may be introduced into the cantilever deck 100 by tightening the nut so that a tensile force is introduced into the fixing bar 213 .

An angle reinforcing part 2125 is provided between the fixing part 2121 and the support part 2122 to reinforce the rigidity between the fixing part 2121 and the support part 2122 when a tensile force is applied to the fixing rod, and Deformation of the 2121 and the support 2122 can be prevented from occurring.

Hereinafter, a cantilever construction method of a bridge using the cantilever deck 100, fixtures 200, anchor bolts 300, etc. described above will be described.

When the construction of the bridge substructure is completed, the girder 1 is installed.

When the necessary girder installation is completed, the cantilever deck 100 integrally provided with the fixture 200 is placed on the outer upper part of the outermost girder 1 without the need to install a support under the cantilever deck 100. do.

When lifting and mounting the cantilever deck 100, one cantilever deck 100 may be lifted and mounted, and as shown in FIGS. 17 and 18, the cantilever deck 100 2 It can be lifted and mounted by combining one or three.

When fastening the lifting bracket 500, bolt holes 231 and 251 formed in the fixture 200 may be used, and deck bolts 600 previously fixed to the cantilever deck 100 may be used.

In addition, by fastening the anchor bolt 300 at the top of the fixing part 270 using the fixture 200, the cantilever deck 100 integrally provided with the fixture 200 and the fixture 200 is maximally constructed. It is fixed to the outer girder (1).

When the fixing work of the cantilever deck 100 is completed, the cantilever construction of the bridge is completed through the process of pouring and curing cast-in-place concrete on the upper part of the girder 1 and the cantilever deck 100.

When the hardening of the cast-in-place concrete is completed by the above process, the concrete is hardened while the upward moment acts on the cantilever deck, preventing deflection of the free end of the cantilever deck and increasing the bending stiffness. do.

The configurations of the present invention described above (embodiments of cantilever decks, embodiments of fixtures, prestress members, anchor bolts, lifting brackets, deck bolts, etc.) can be cross-applied to each other and implemented in various forms.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

100. Cantilever deck
110. Main body
111. Top 112. Bottom
113. Front and rear 114. Side
120. Mounting part
121. Top 122. Bottom
123. Front and back 124. Side
130. Wall
131. Connection protrusion 132. Connection groove
200. Fixtures
210. Deck anchorage
220. Connections
230. Mounting part 231. Bolt hole
240. Inclined part 241. Forced displacement bolt hole
250. Compression part 251. Bolt hole
260. Support
270. Fixing part 271. Anchor fixing hole
280. Forced displacement bolt
290. Fixed bolt
211. Reinforcements
2111. Fixing rod fixing hole
212. Fixed bracket
2121. Fixed part 2122. Support part
2123. Anchor fixing hole 2124. Fixing bar fixing hole
2125. Angle reinforcement part
213. Fixed bar
2131. Nut
300. Anchor bolt 310. Nut
400. Prestress member
410. Strand 420. Turnbuckle
500. Lifting bracket 600. Deck bolt
1. Girder
a. The angle between the horizontal line and the fixing part, and the angle between the horizontal line and the crimping part.
t. fixture thickness
H. Thickness of cantilever deck
l. Length of deck anchorage
h1. length of connection
h2. length of support
w1. Width of body portion 110
w2. Width of the mounting portion 120

Claims (13)

In the method of constructing the cantilever of the bridge,
A) Installing the girder (1);
B) Mounting the cantilever deck 100 integrally provided with the fixture 200 on the outer upper part of the outermost girder 1 without installing a support under the cantilever deck 100;
c) fixing the cantilever deck 100 to the outermost girder 1 using the fixture 200;
D) including the step of placing cast-in-place concrete on the top of the girder 1 and the cantilever deck 100,
The fixture 200 includes a deck fixing unit 210 embedded in the cantilever deck 100;
A connection part 220 provided upward from the deck fixing part 210 and a part thereof buried in the cantilever deck 100;
a mounting portion 230 provided in a horizontal direction from the connecting portion 220;
an inclined portion 240 inclined downward from the holding portion 230;
A compression part 250 provided from the inclined part 240 toward the outermost girder 1;
a support portion 260 provided downwardly from the compression portion 250;
It is provided from the support part 260 toward the inside of the bridge and includes a fixing part 270 having an anchor fixing hole 271 through which the anchor bolt 300 passes,
By fastening the anchor bolt 300 to the fixing part 270, the fixture 200 and the cantilever deck 100 integrally provided with the fixture 200 are fixed to the outermost girder 1,
As the lower surfaces of the support part 260 and the fixing part 270 are fastened to the anchor bolt 300 in a state where they are spaced apart from the upper surface of the girder 1, downward prestress is always applied to the fixing part 270. to be
Bridge cantilever construction method. delete delete According to claim 1,
The cantilever deck 100 includes a body portion 110 and a mounting portion 120,
The ratio of the width (w2) of the mounting portion 120: the length of the crimping portion 250 is 1: 0.7 to 1, characterized in that
Bridge cantilever construction method. According to claim 4,
The cantilever deck 100 further includes a wall portion 130 integrally provided above the end portion of the body portion 110,
A connection protrusion 131 is provided on one end of the wall 130, and a connection groove 132 is provided on the top of the other end.
Bridge cantilever construction method. The method of any one of claims 1, 4 and 5,
The length (h2) of the support portion 260 is characterized by the same as the following formula
h2= (0.85~0.95)H + t
(H: thickness of cantilever deck 100, t: thickness of fixture 200)
Bridge cantilever construction method. The method of any one of claims 1, 4 and 5,
The length l of the deck fixing part 210 is 16 to 20 times the thickness t of the fixture 200 or 3/10 to 6/10 the width w1 of the main body 110 doing
Bridge cantilever construction method. The method of any one of claims 1, 4 and 5,
The deck fixing part 210 and the connection part 220, the connection part 220 and the holding part 230, the compression part 250 and the support part 260, the support part 260 and the fixing part 270 are respectively Characterized in that the center line forms a right angle
Bridge cantilever construction method. The method of any one of claims 1, 4 and 5,
Characterized in that the angle (a) between the center line of the crimping part 250 and the horizontal line and the angle (a) between the center line and the horizontal line of the fixing part 270 are 0.5 to 1.5 degrees
Bridge cantilever construction method. The method of any one of claims 1, 4 and 5,
The inclined portion 240 is provided with a forced displacement bolt hole 241,
Characterized in that the forced displacement bolt 280 is fastened to the forced displacement bolt hole 241
Bridge cantilever construction method. The method of any one of claims 1, 4 and 5,
A prestress member 400 is provided on the top of the cantilever deck 100
Bridge cantilever construction method. The method of any one of claims 1, 4 and 5,
The fixture 200 further includes a reinforcement part 211 integrally provided upward from the end of the deck anchoring part 210,
A part of the reinforcement part 211 is embedded in the cantilever deck 100, an upper part of the reinforcement part 211 protrudes above the cantilever deck 100, and the reinforcement part 211 protrudes above the cantilever deck 100 A fixing rod fixing hole 2111 is provided,
The fixing bracket 212 provided with the fixing bar fixing hole 2124 is fastened to the upper part of the fixing part 270,
The fixing rod 213 is fastened to pass through the fixing rod fixing hole 2111 of the reinforcing part 211 and the fixing rod fixing hole 2124 of the fixing bracket 212, so that the cantilever deck 100 has a positive characterized by introducing a bending moment
Bridge cantilever construction method. According to claim 12,
The fixing bracket 212 includes a fixing part 2121 fastened to contact the fixing part 270; It includes a support part 2122 integrally provided while forming a right angle with the fixing part 2121,
An anchor fixing hole 2123 is provided in the fixing part 2121,
The fixing bar fixing hole 2124 is provided in the support part 2122
Bridge cantilever construction method.

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