KR101824874B1 - Free rotating prefraction girder and manufacturing method of prefraction girder - Google Patents

Abstract

The present invention relates to a preflextion girder support structure free from rotation displacement and a method for manufacturing a preflextion girder for providing preflextion to a girder having an upper flange and a lower flange spaced from each other and an abdomen connecting the upper flange and the lower flange. The preflextion girder support structure free from rotation displacement comprises: a pair or guide beams installed on both sides of the girder; a pair of secondary beams installed inside each of the guide beams and coupled to the guide beams to be able to slide up and down; a pair of rotary support units coupled to the inside of each of the secondary beams, and supporting the upper and lower sides of the upper flange so as to move up and down according to up and down sliding of the secondary beams for moving the upper flange up and down and at the same time accommodating the rotation displacement of the girder generated by a flection of the girder. Therefore, an effect of accommodating the rotation displacement of the girder can be provided.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a prefraction girder supporting structure free from rotational displacement and a method of manufacturing a prefraction girder,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a prefractional girder supporting structure free from rotational displacement and a method of manufacturing a prefractional girder.

In general, the prefraction girder is constructed by pouring concrete around a lower flange under the condition that a load is applied to a girder of H-shaped steel or the like made of a steel beam by a hydraulic jack, and the restoring force of the steel beam And the compressive prestress is introduced into the concrete placed in the lower flange.

In order to manufacture a prefractional girder by using a hydraulic jack as described above, two girders are arranged so as to face each other up and down, and a hydraulic jack is disposed between the girders and the girders so as to pressurize the two girders. There is a way.

However, since the prefractional girder fabrication method as described above requires a very large equipment, a large amount of cost is required to equip the fabrication site and equipment, and a long prefraction girder is manufactured because the girder is manufactured up and down. The vertical and horizontal displacements become too large to introduce the pre-flex, and the accuracy of the pre-flex is low. The rotation of the steel beam can cause an accident due to the conduction of the girder at the manufacturing site of the prefraction girder. There is a problem that it is difficult to introduce sufficient pre-flex because the rotational displacement of the girder is restricted in the portion where the hydraulic pressure is applied.

In order to solve the above problems, there have been developed techniques for manufacturing a preplaced girder which is capable of receiving a rotation of a steel beam during manufacture of a preplaced girder, thereby preventing a safety accident.

For example, Korean Patent No. 10-1319993 discloses a method of manufacturing a preflex girder using a rotation preventing device (see Figs. 4A and 4B). In this prior art, a vertical beam-type both side wall frame 310 spaced apart from each other in the longitudinal direction of the steel beam 200 is provided on both sides of the steel beam 200 so as to introduce an upward camber, And the inner side support table 330 formed continuously in the longitudinal direction is installed on the floor and the steel beam 200 is attached to the lower side point portion 350 provided on the inner bottom of the production table 300 Installing the concrete block 400 on the upper surface of the steel beam 200 using the anti-rotation device 500; Forming a casing concrete (240) by using a casing mold (250) installed under the steel beam (200); And removing the concrete block (400) and the casing form (250) from the concrete block (400) and introducing refraction into the casing concrete, wherein the rotation preventing device (500) penetrates the concrete block The horizontal support rods 510 having a length extending to the upper surface of the inner support table 330 of the work table 300 and the horizontal support rods 510 are supported on the inner support table 330 of the work table 300 And a displacement restoration body 520 that restrains the horizontal support rod 510 when the horizontal support rod 510 is about to be rotated left and right and upward and downward. The method of manufacturing a preflexed girder according to claim 1, It is possible to secure the economical efficiency by minimizing the flex girder manufacturing facility, but it is also possible to increase the efficiency of the prefabricated load, And a method of manufacturing a preflex girder capable of preventing a collapse of the preflex girder.

However, in order to introduce a pre-flex into a girder, the above-mentioned prior art has difficulty in loading sufficient load for introduction of pre-fracture by using only the weight of a steel beam, a concrete block, a casing form and a concrete for casing concrete, There is a problem that it is still difficult to accommodate the rotational displacement caused by the bending occurring in the production stand as the girder is curved. In addition, since both ends of the lower flange are completely restrained by the fabrication table provided on both sides, there is a problem in that the concrete can not be laid over the entire lower flange. Thus, both ends of the girder are cut off or the pre- It is difficult to install and cure the concrete twice, so that the workability and economical efficiency are lowered, and it is difficult to say that the pre-flex is introduced to both ends of the girder, and thus there is a problem that the integrity is poor.

Patent 1: Korean Patent No. 10-1319993

In order to solve the above-mentioned problems, the present invention is to solve the above-mentioned problems, and it is an object of the present invention to provide a rotary support apparatus which is capable of supporting a girder A fracture girder supporting structure and a method of manufacturing a free flange girder.

A prefractional girder supporting structure free from rotational displacement according to an example of the present invention is for introducing a prefraction to a girder including an upper flange and a lower flange spaced from each other and a belly connecting the upper flange and the lower flange A pair of guide beams installed on both sides of the girder; A pair of auxiliary beams installed inside each of the pair of guide beams and slidably coupled to the guide beams; And the upper and lower sides of the upper flange are moved upward and downward in accordance with the vertical sliding of the auxiliary beam to move the girder upward and downward and at the same time, And a pair of rotation supporting devices capable of receiving the rotation of the girder.

The rotation support device may further include a bracket coupled to the inside of the auxiliary beam and supporting the lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, an elastic pad coupled to the inside of the auxiliary beam, An elastic pad guide for supporting the upper side, and an elastic pad provided between the elastic pad guide and the upper flange.

The apparatus may further include an elastic pad brace for coupling the elastic pad guide and the auxiliary beam.

The rotation support device may further include a first member coupled to the inside of the auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member, A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, a bracket coupled to the inside of the second member and abutting on the upper side of the upper flange, And a bracket for supporting the bracket.

A prefractional girder supporting structure free from rotational displacement according to another exemplary embodiment of the present invention is characterized in that it includes an upper flange and a lower flange spaced apart from each other and a girder connecting the upper flange and the lower flange, A pair of second guide beams installed on both sides of the girder; A pair of second auxiliary beams installed inside and fixed to the pair of second guide beams, respectively; A pair of second auxiliary beams which are coupled to the inside of each of the pair of second auxiliary beams and which support upper and lower sides of the upper flange to support the girder and which can receive rotation of the girder caused by the warping of the girder And a rotation support device.

The rotation support device may further include a bracket coupled to the inside of the second auxiliary beam and supporting the lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, An elastic pad guide for supporting an upper side of the upper flange, and an elastic pad provided between the elastic pad guide and the upper flange.

The apparatus may further include a count weight support for coupling the elastic pad guide, the second auxiliary beam, and the second guide beam.

The rotation support device may further comprise a first member coupled to the inside of the second auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member, A bracket that is coupled to the inside of the second member and that is held in contact with the lower side of the upper flange, and a bracket that is coupled to the inside of the second member and is provided on the upper side of the upper flange And a bracket that is held in abutting contact with the base.

A method of manufacturing a prefractional girder according to an example of the present invention comprises the steps of: preparing a girder including an upper flange and a lower flange spaced apart from each other, and a belly connecting the upper flange and the lower flange; Wherein an end support is provided at both ends of the girder, an inner support is provided at two points in the center of the girder, a count weight is provided above the end support, a jack is provided below the inner support, Pressing the girder upward by a jack to cause warpage; Installing a girder to form a lower flange concrete on the girder, installing a reinforcing bar, a sheath tube, and an anchorage on the inner side of the girder, and pouring concrete; And removing the pressure of the jack after the concrete is cured, wherein the inner support includes a pair of guide beams installed on both sides of the girder; A pair of auxiliary beams installed inside each of the pair of guide beams and slidably coupled to the guide beams; And the upper and lower sides of the upper flange are moved upward and downward in accordance with the vertical sliding of the auxiliary beam to move the girder upward and downward and at the same time, A pair of second guide beams installed on both sides of the girder, and a pair of second guide beams installed on both sides of the girder; A pair of second auxiliary beams installed inside and fixed to the pair of second guide beams, respectively; A pair of second auxiliary beams which are coupled to the inside of each of the pair of second auxiliary beams and which support upper and lower sides of the upper flange to support the girder and which can receive rotation of the girder caused by the warping of the girder And a rotation support device.

The rotation support device of the inner support includes a bracket coupled to the inner side of the auxiliary beam and supporting the lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, An elastic pad guide for supporting an upper side of the upper flange, and an elastic pad provided between the elastic pad guide and the upper flange.

The rotation support device of the inner support may further include a first member coupled to the inner side of the auxiliary beam, a second member facing the first member, and a second member disposed between the first and second members, A bracket that is coupled to the inside of the second member and that is held in contact with the lower side of the upper flange, a bracket that is coupled to the inside of the second member and that is disposed on the upper side of the upper flange And a bracket that is held in abutment with the abutting portion.

The rotation support device of the end support includes a bracket coupled to the inside of the second auxiliary beam and supporting the lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, An elastic pad guide coupled to the upper flange and supporting the upper side of the upper flange, and an elastic pad provided between the elastic pad guide and the upper flange.

The rotation support device of the end support includes a first member coupled to the inside of the second auxiliary beam, a second member facing the first member, and a second member disposed between the first and second members A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, a bracket coupled to the inside of the second member, And a bracket that is held in contact with the upper side of the bracket.

According to another aspect of the present invention, there is provided a method of manufacturing a prefractional girder, comprising: preparing a girder including an upper flange and a lower flange spaced apart from each other; and a girder connecting the upper flange and the lower flange; Wherein an inner support is provided at two points in the center of the girder, a jack is provided on the upper side of the inner support, a count weight is provided on the upper side of the jack, Pressing the girder downward to cause warpage; Installing a girder to form a lower flange concrete on the girder, installing a reinforcing bar, a sheath tube, and an anchorage on the inner side of the girder, and pouring concrete; And removing the pressure of the jack after the concrete is cured, wherein the inner support includes a pair of guide beams installed on both sides of the girder; A pair of auxiliary beams installed inside each of the pair of guide beams and slidably coupled to the guide beams; And the upper and lower sides of the upper flange are moved upward and downward in accordance with the vertical sliding of the auxiliary beam to move the girder upward and downward and at the same time, A pair of second guide beams installed on both sides of the girder, and a pair of second guide beams installed on both sides of the girder; A pair of second auxiliary beams installed inside and fixed to the pair of second guide beams, respectively; A pair of second auxiliary beams which are coupled to the inside of each of the pair of second auxiliary beams and which support upper and lower sides of the upper flange to support the girder and which can receive rotation of the girder caused by the warping of the girder And a rotation support device.

The rotation support device of the inner support includes a bracket coupled to the inner side of the auxiliary beam and supporting the lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, An elastic pad guide for supporting an upper side of the upper flange, and an elastic pad provided between the elastic pad guide and the upper flange.

The rotation support device of the inner support may further include a first member coupled to the inner side of the auxiliary beam, a second member facing the first member, and a second member disposed between the first and second members, A bracket that is coupled to the inside of the second member and that is held in contact with the lower side of the upper flange, a bracket that is coupled to the inside of the second member and that is disposed on the upper side of the upper flange And a bracket that is held in abutment with the abutting portion.

The rotation support device of the end support includes a bracket coupled to the inside of the second auxiliary beam and supporting the lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, An elastic pad guide coupled to the upper flange and supporting the upper side of the upper flange, and an elastic pad provided between the elastic pad guide and the upper flange.

The rotation support device of the end support includes a first member coupled to the inside of the second auxiliary beam, a second member facing the first member, and a second member disposed between the first and second members A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, a bracket coupled to the inside of the second member, And a bracket that is held in contact with the upper side of the bracket.

Further, the girder may be a honeycomb girder having hexagonal cut-out portions formed along the axial direction in the abdomen.

In addition, the girder may be formed in advance so that the central portion is convex upward or downward.

According to still another aspect of the present invention, there is provided a method of manufacturing a prefractional girder comprising the steps of: preparing a girder including an upper flange and a lower flange spaced apart from each other, and an abdomen connecting the upper flange and the lower flange; An end support is provided at both ends of the girder, and an inner support is provided at two points in the center of the girder. An auxiliary girder is provided on the upper side of the girder, and between the girder and the inner girder And the auxiliary girder is fixed to both the end support and the inner support, and the girder is fixed only to the inner support and is vertically flowable to the end support, So as to generate warpage; Installing a girder to form a lower flange concrete on the girder, installing a reinforcing bar, a sheath tube, and an anchorage on the inner side of the girder, and pouring concrete; And removing the pressure of the jack after the concrete is cured, wherein the inner support includes a pair of second guide beams installed on both sides of the girder; A pair of second auxiliary beams installed inside and fixed to each of the pair of second guide beams, a pair of second auxiliary beams coupled to the inside of each of the pair of second auxiliary beams and supporting upper and lower sides of the upper flange, And a pair of rotation supporting devices for supporting the girders and capable of receiving the rotation of the girders caused by the warping of the girders.

The rotation support device of the inner support includes a bracket coupled to the inside of the second auxiliary beam and supporting the lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, An elastic pad guide coupled to the upper flange and supporting an upper side of the upper flange, and an elastic pad provided between the elastic pad guide and the upper flange.

The rotation support device of the inner support includes a first member coupled to the inside of the second auxiliary beam, a second member facing the first member, and a second member installed between the first and second members, A bracket that is coupled to the inside of the second member and that is held in contact with the lower side of the upper flange, a bracket coupled to the inside of the second member, And a bracket that is held in contact with the upper side of the flange.

The present invention can provide an effect of effectively introducing the prefraction load by accommodating the rotational displacement due to the curvature of the girder while firmly supporting the girder with the rotation support device.

1A is a view showing a method of manufacturing a prefractional girder according to an example of the present invention by pressing a jack under the inner support.
Fig. 1B is a cross-sectional view and an exploded perspective view showing a state of the inner support of Fig. 1A.
Fig. 1C is an exploded perspective view showing another embodiment of the inner support of Fig. 1A and an enlarged view showing the rotation of the girder. Fig.
Fig. 1D is a cross-sectional view and a side view showing a state of the end support of Fig. 1A.
2A is a view showing a method of manufacturing a prefractional girder according to an example of the present invention by pressing a jack on the upper side of an inner support.
2B is a cross-sectional view showing a state of the inner support of FIG. 2A.
Fig. 2C is a sectional view showing a state of the end support of Fig. 1A. Fig.
3A is a view showing a method of manufacturing a prefractional girder according to an example of the present invention by pressing the upper side between the inner support and the end support.
Fig. 3B is a plan view showing a state of the end support of Fig. 3A. Fig.
3C is a cross-sectional view and an exploded perspective view showing a state of the inner support of Fig. 3A.
Fig. 3D is a cross-sectional view and an exploded perspective view of another example showing the state of the inner support of Fig. 3A.
4 is a drawing of the prior art.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In the drawings, like reference numerals are used to refer to like elements throughout the drawings, even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, May be "connected "," coupled "or" connected ".

Hereinafter, a prefractional girder supporting structure having a free rotation displacement according to an example of the present invention will be described in detail with reference to FIGS. 1 to 3. FIG.

1, a prefractional girder supporting structure having a free rotational displacement according to an exemplary embodiment of the present invention includes a girder 10 including an upper flange and a lower flange spaced apart from each other, and an abdomen connecting the upper flange and the lower flange, A pair of guide beams 20 provided on both sides of the girder 10 and guide beams 20 provided inside the pair of guide beams 20 to guide the free rays to the guide beam 20, A pair of auxiliary beams 30 which are slidably coupled in an up and down direction and are coupled to the inside of each of the pair of auxiliary beams 30 so as to support upper and lower sides of the upper flange, Which is capable of receiving the rotation of the girder 10 caused by the bending (curvature) of the girder 10 while moving the girder 10 vertically while moving upward and downward in accordance with the movement of the girder 10, (40).

The girder 10 may be an upper flange and a lower flange spaced apart from each other, an H-shaped steel including an abdomen connecting the upper flange and the lower flange, or an I-shaped steel, and the thickness and width of the web and flange of the steel You can choose.

A pair of guide beams 20 are provided on the left and right sides of the girder 10 to support the auxiliary beam 30, which will be described later, so as to be slidable up and down. The guide beam 20 can be anything as long as it can firmly support the auxiliary beam 30 and the girder 10, such as an H-shaped beam.

The auxiliary beam 30 is vertically slidably coupled to the inside of the guide beam 20, and an H-shaped steel or the like can be used in the same manner as the guide beam 20.

It is preferable that the auxiliary beam 30 is slidably coupled to the guide beam 20 in the vertical direction but is firmly supported without flowing in the outward direction. A steel plate or the like is installed so that the flange of the guide beam 20 and the auxiliary beam 30 are in contact with each other so that the guide beam 20 which is an H-shaped beam and the auxiliary beam 30 can be slidably engaged with each other, Can be used. That is, the beam may be welded to one of the flanges of the guide beam 20 or the auxiliary beam 30, and the other flange may simply be wrapped.

A jack 80 (including a hydraulic jack) may be installed between the lower side of the auxiliary beam 30 and the ground. According to the operation of the jack 80, the auxiliary beam 30 is raised or lowered with respect to the guide beam 20.

Also, the jack 80 may be provided on the upper side of the auxiliary beam 30. In this case, a count weight 50 may be provided on the upper side of the jack 80.

The rotation support apparatus 40 is coupled to the inside of each of the pair of auxiliary beams 30 and supports the upper and lower sides of the upper flange. Therefore, the rotation support apparatus 40 moves up and down the auxiliary beam 30 to move upward and downward, thereby moving the girder 10 upward and downward to warp or curl. When the girder 10 is bent, the flange of the girder 10 relative to the rotary support apparatus 40 is inclined, that is, the rotary support apparatus 40 and the flange are brought into contact with one side and the other side is separated, By accommodating the triangular space, the girder 10 can be curved.

1B, an example of the rotation support device 40 includes a bracket 42 coupled to the inside of the auxiliary beam 30 by welding or the like to support the lower side of the upper flange, An elastic pad guide 44 provided inside the auxiliary beam 30 by welding or the like and supporting the upper side of the upper flange 44, And an elastic pad 43 disposed between the upper flanges.

The bracket 42 can support the upper flange of the girder 10 from below and cause the girder 10 to be bent when the jack 80 is actuated. The bracket 42 is provided with binding plates on both sides to prevent separation of the elastic pad 43 described later or can be directly bonded to the elastic pad 43 without a binding plate.

The elastic pad guide 44 supports the upper flange downward from the upper side of the upper flange, so that the upper flange can be stably supported when the hydraulic pad acts. Also, the elastic pad guide 44 may be provided with binding plates on both sides to prevent the elastic pad 43 from being separated from the elastic pad 43, or may be bonded directly to the elastic pad 43 without a binding plate.

The elastic pad 43 is provided between the upper flange and the lower flange and between the upper flange and the bracket 42 and between the upper flange and the elastic pad guide 44. As the girder 10 is curved, It is possible to accommodate the displacement, that is, the triangular space, occurring between the brackets 42 and the contact surface between the upper flange and the elastic pad guide 44. That is, one side of the upper flange and the elastic pad guide 44 are in contact with each other between the upper flange and the bracket 42 and the space between the upper flange and the elastic pad guide 44 is spaced apart from each other. ) Is compressed more and the other side is less compressed, thereby accommodating the space on the triangle well. For this purpose, the elastic pad 43 may be made of rubber having high elasticity, or rubber having a plurality of steel plates inserted therein and having high elasticity.

In addition, an elastic pad brace 45 may be provided on the upper side of the elastic pad guide 44. The elastic pad brace 45 is formed by joining the elastic pad guide 44 and the auxiliary beams 30 on both sides together by welding or the like at the upper side of the elastic pad guide 44 to firmly support the curved girder 10 .

1C, another example of the rotation supporting device 40 includes a first member 47 coupled to the inside of the auxiliary beam 30 by welding or the like, a first member 47 facing the first member 47, A second member 48 disposed between the first member 47 and the second member 48 and adapted to be rotatably engaged with the first member 47 and the second member 48, A bracket 42 coupled to the inside of the second member 48 and held in contact with the lower side of the upper flange, a bracket 42 coupled to the inside of the second member 48 and held in contact with the upper side of the upper flange, (42).

The first member 47 is coupled to the inner side of the auxiliary beam 30 by welding or the like, and may be a rectangular plate. The second member 48 is installed facing the first member 47, and may be a steel sheet having the same shape and material as the first member 47. The bearing 49 may be welded to the first member 47 or may be a circular shape integrally formed with the first member 47 and at the same time the bearing 49 may be inserted into the second member 48 A circular through hole or a groove may be formed. Further, the bearing 49 is coupled to the second member 48, and the through hole or groove can be formed in the first member 47. [ An auxiliary bearing may be inserted between the bearing 49 and the through hole or groove, or a lubricant may be injected.

A bracket 42, which is in contact with the upper side and the lower side of the upper flange, may be coupled to the inside of the second member 48 by welding or the like. Therefore, the upper and lower brackets 42 firmly support the upper flange, and the inclination caused by the curvature of the girder 10 accommodates the rotation of the second member 48. That is, when the jack 80 is pressed to raise the girder 10, the girder 10 is bent, and the inclination of the flange generated thereby is facilitated by the rotary support apparatus 40 provided with the bearing 49 Lt; / RTI >

1d, a prefractional girder supporting structure having a free rotation displacement according to an exemplary embodiment of the present invention includes a girder 10 including an upper flange and a lower flange spaced from each other, and a girder connecting the upper flange and the lower flange, A pair of second guide beams 22 provided on both sides of the girder 10 and a pair of second guide beams 22 installed inside and fixed to the pair of second guide beams 22, A second auxiliary beam (32) is coupled to the inside of each of the pair of second auxiliary beams (32) and supports upper and lower sides of the upper flange to support the twin girders (10) And a pair of rotation supporting devices 40 capable of receiving the rotation of the girder 10 caused by the warping (curvature).

This embodiment is similar to the above-described embodiment. However, the second auxiliary beam 32 differs from the above-described embodiment in that the second auxiliary beam 32 is installed inside the second guide beam 22 and is fixed by welding, bolts, nuts, etc., and no sliding occurs in the vertical direction .

Hereinafter, a method of manufacturing a prefractional girder according to an example of the present invention will be described in detail. For the components used in the manufacture of prefractional girders, see the description above.

Referring to FIG. 1, a method of manufacturing a prefractional girder according to an embodiment of the present invention includes the steps of preparing a girder 10 including upper and lower flanges spaced apart from each other, and an abdomen connecting the upper flange and the lower flange; An end support 60 is provided at both ends of the girder 10 and an inner support 70 is installed at two points in the center of the girder 10 and a count weight 50 Providing a jack 80 on a lower side of the inner support 70 and pressing the girder 10 upward to cause warpage; A step 90 for forming a lower flange concrete is installed on the girder 10 so as to be suspended from the girder 10 and a reinforcing bar, a sheath tube and a fixing hole are installed inside the form 90, ; And removing the mold 90 and releasing the pressure of the jack 80 after the concrete is cured.

The step of preparing the girder 10 is a step of preparing the girder 10 including the upper flange and the lower flange, and the abdomen connecting the upper flange and the lower flange. The girder 10 is for introducing a pre-fracture to construct a bridge, and it is desirable that the girder 10 has sufficient rigidity to be able to construct a bridge.

The step of pressing the girder 10 upward to cause the warp to occur is a step of pressing the girder 10 upward by the jack 80 so that the girder 10 is bent or curved.

In this embodiment, an end support 60 is provided at both ends of the girder 10, and an inner support 70 is installed at two points in the center of the girder 10, and on the upper side of the end support 60, (50), and a jack (80) is provided below the inner support base (70).

The count weight 50 is suitable enough to sufficiently support pressurization by the hydraulic pressure.

An inner support 70 provided at two centers of the girder 10 is installed inside each of the pair of guide beams 20 installed on both sides of the girder 10 and the pair of guide beams 20 A pair of auxiliary beams 30 which are slidably coupled to the guide beams 20 in an up-and-down direction, a pair of auxiliary beams 30 which are coupled to the inside of the pair of auxiliary beams 30, The pair of girders 10 can be moved up and down in accordance with the upward and downward sliding of the beam 30 to vertically move the girder 10 and to receive the rotation of the girder 10 caused by the bending of the girder 10 The rotation support device 40 of Fig. The rotating support device of this embodiment refers to the above-described embodiment.

The end support frames 60 provided at both ends of the girder 10 include a pair of second guide beams 22 provided on both sides of the girder 10 and a pair of second guide beams 22 A pair of second auxiliary beams 32 installed and fixed to the pair of second auxiliary beams 32 and supported on the upper and lower sides of the upper flange to support the girder 10 And a pair of rotation supporting devices 40 capable of receiving the rotation of the girder 10 generated due to the warping of the girder 10. The rotation support device of this embodiment also refers to the above-described embodiment.

Accordingly, in the present embodiment, by pressing the jack 80 provided at the lower side of the inner support 70 at the two central points, the girder 10 is bent upward, i.e., curved upward. At this time, the rotation of the girder 10 is stably accommodated by the rotary support device 40 provided on the end support 60 and the inner support 70, thereby effectively introducing the pre-fracture.

The step of pouring concrete includes the steps of installing a mold 90 for hitting the lower flange concrete on the girder 10, installing a reinforcing bar, a sheath pipe, and a fixture on the inside of the mold 90, to be. At this stage, the installation of the form 90 and the installation of the reinforcing bars, sheath pipes, fixtures, etc. can be performed in accordance with the work situation.

The step of releasing the pressure of the jack 80 includes the step of removing the form 90 after the concrete poured under the girder 10 is cured and thereafter releasing the pressure of the jack 80 to introduce the pre- to be. That is, after completion of the curing of the lower flange concrete, the form 90 is removed and the jack 80 releases the pressure, thereby introducing the pre-fracture into the girder 10. In this step, either the method of first removing the form 90 and then releasing the hydraulic pressure, or the method of first releasing the hydraulic pressure and then removing the form 90 may be used.

When the fabrication is completed as described above, it is preferable that the prefraction girder 10 is carried or stacked under the same supporting condition as the fabrication step. Therefore, the variation of the prefraction introduced into the girder 10 can be minimized before the bridge construction.

Referring to FIG. 2, a method of manufacturing a prefractional girder according to another exemplary embodiment of the present invention includes a step of preparing a girder 10 including upper and lower flanges spaced apart from each other, and an abdomen connecting the upper flange and the lower flange ; An end support 60 is installed at both ends of the girder 10 and an inner support 70 is installed at two points in the center of the girder 10. A jack 80 is provided on the inner support 70, (50) is provided on the upper side of the jack (80), and then the girder (10) is pressed downward by the jack (80) to cause warpage; A step 90 for forming a lower flange concrete is installed on the girder 10 so as to be suspended from the girder 10 and a reinforcing bar, a sheath tube and a fixing hole are installed inside the form 90, ; And removing the mold 90 and releasing the pressure of the jack 80 after the concrete is cured.

This embodiment is similar to the above-described example. The present embodiment differs from the first embodiment in that a jack 80 is provided on the upper side of the inner support 70 and a counter weight 50 is provided on the upper side of the jack 80. That is, in this embodiment, the hydraulic pressure is applied downward by a jack 80 provided on the upper side of the inner support 70 of the center two points to bend the girder 10 downward, and then the mold 90 is installed, After the mold 90 is removed, the pressure is released.

(52) for coupling the elastic pad guide (44) with the second auxiliary beam (32) and the second guide beam (22). That is, the count weight support base 52 can be provided on the upper side of the second auxiliary beam 32 to support the count weight 50.

3, a method of manufacturing a prefractional girder according to another embodiment of the present invention includes preparing a girder 10 including an upper flange and a lower flange spaced from each other and a belly connecting the upper flange and the lower flange, ; An end support 60 is provided at both ends of the girder 10 and an inner support 70 is installed at two points in the center of the girder 10. An auxiliary girder 12 is provided on the upper side of the girder 10, And a jack 80 is provided between the girder 10 and the auxiliary girder 12 between the end support 60 and the inner support 70. The auxiliary girder 12 is connected to the end support The girder 10 is fixed only to the inner support 70 and is vertically movable to the end support 60. The jack 80 is fixed to the inner support 70, To press the girder (10) downward to cause warpage; A step 90 for forming a lower flange concrete is installed on the girder 10 so as to be suspended from the girder 10 and a reinforcing bar, a sheath tube and a fixing hole are installed inside the form 90, ; And a step of removing the mold 90 after the concrete is cured and releasing the pressure of the jack 80. The inner support 70 is installed on both sides of the girder 10 A pair of second guide beams 22; A pair of second auxiliary beams 32 installed inside and fixed to the pair of second guide beams 22; The upper and lower flanges are supported on the upper and lower sides of the pair of second auxiliary beams 32 to support the girder 10 and the girder 10, 10 that are rotatable about the axis of rotation.

The present embodiment is different in that an auxiliary girder 12 is provided on the upper side of the girder 10. The auxiliary girder 12 is provided on the upper side of the girder 10 and fixed to both the inner support 70 and the end support 60. [

The jack 80 is installed between the girder 10 and the auxiliary girder 12 between the end support 60 and the inner support 70 and presses the end of the girder 10 downward. That is, the girder 10 of the present embodiment is rotatably supported on the inner support 70, and is installed on the end support 60 so as to be vertically movable.

The rotation support device of this embodiment is the same as the above-described example.

The girders 10 described above can be made of a honeycomb girder having hexagonal cut-outs formed along the axial direction in the abdomen. Such a honeycomb girder can save material by removing unnecessary portions for bending stress.

Further, the girder 10 may be curved in advance so that its central portion is convex upward or downward.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all the constituent elements may be constituted or operated selectively in combination with one or more. Furthermore, the terms "comprises", "comprising", or "having" described above mean that a component can be implanted unless otherwise specifically stated, But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: Girder
12: Auxiliary girder
20: guide beam
22: second guide beam
30: auxiliary beam
32: Second auxiliary beam
40:
42: Bracket
43: elastic pad
44: Elastic pad guide
45: Elastic pad bracing
47: first member
48: second member
49: Bearings
50: Count weight
52: Count weight support
60: end support
70: inner support
80: Jack
90: Form

Claims (23)

delete The upper flange and the lower flange spaced apart from each other, and the abdomen connecting the upper flange and the lower flange,
A pair of guide beams installed on both sides of the girder;
A pair of auxiliary beams installed inside each of the pair of guide beams and slidably coupled to the guide beams;
And the upper and lower sides of the upper flange are moved upward and downward in accordance with the vertical sliding of the auxiliary beam to move the girder upward and downward and at the same time, And a pair of rotation supporting devices capable of receiving the rotation of the girders,
The rotation support device includes:
A bracket coupled to the inside of the auxiliary beam and supporting a lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, an elastic pad coupled to the inside of the auxiliary beam and supporting the upper side of the upper flange, And an elastic pad provided between the elastic pad guide and the upper flange.

The method of claim 2,
And an elastic pad brace for coupling the elastic pad guide and the auxiliary beam to each other.
The upper flange and the lower flange spaced apart from each other, and the abdomen connecting the upper flange and the lower flange,
A pair of guide beams installed on both sides of the girder;
A pair of auxiliary beams installed inside each of the pair of guide beams and slidably coupled to the guide beams;
And the upper and lower sides of the upper flange are moved upward and downward in accordance with the vertical sliding of the auxiliary beam to move the girder upward and downward and at the same time, And a pair of rotation supporting devices capable of receiving the rotation of the girders,
The rotation support device includes:
A first member coupled to the inside of the auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member such that the first member and the second member are mutually rotatable A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, and a bracket coupled to the inside of the second member and held in contact with the upper side of the upper flange Free prefraction girder support structure.
delete The upper flange and the lower flange spaced apart from each other, and the abdomen connecting the upper flange and the lower flange,
A pair of second guide beams installed on both sides of the girder;
A pair of second auxiliary beams installed inside and fixed to the pair of second guide beams, respectively;
A pair of second auxiliary beams which are coupled to the inside of each of the pair of second auxiliary beams and which support upper and lower sides of the upper flange to support the girder and which can receive rotation of the girder caused by the warping of the girder A rotation support device,
The rotation support device includes:
A bracket coupled to the inside of the second auxiliary beam and supporting a lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, And an elastic pad provided between the elastic pad guide and the upper flange. The prefractional girder supporting structure according to claim 1,
The method of claim 6,
And a count weight support for coupling the elastic pad guide, the second auxiliary beam, and the second guide beam.
The upper flange and the lower flange spaced apart from each other, and the abdomen connecting the upper flange and the lower flange,
A pair of second guide beams installed on both sides of the girder;
A pair of second auxiliary beams installed inside and fixed to the pair of second guide beams, respectively;
A pair of second auxiliary beams which are coupled to the inside of each of the pair of second auxiliary beams and which support upper and lower sides of the upper flange to support the girder and which can receive rotation of the girder caused by the warping of the girder A rotation support device,
The rotation support device includes:
A first member coupled to the inside of the second auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member, A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, and a bracket coupled to the inside of the second member and held in contact with the upper side of the upper flange, Wherein the free-rotation girder support structure is free from rotational displacement.
Preparing a girder including an upper flange and a lower flange spaced apart from each other, and a abdomen connecting the upper flange and the lower flange;
Wherein an end support is provided at both ends of the girder, an inner support is provided at two points in the center of the girder, a count weight is provided above the end support, a jack is provided below the inner support, Pressing the girder upward by a jack to cause warpage;
Installing a girder to form a lower flange concrete on the girder, installing a reinforcing bar, a sheath tube, and an anchorage on the inner side of the girder, and pouring concrete;
Removing the mold after the concrete is cured and releasing the pressure of the jack,
The inner support includes:
A pair of guide beams installed on both sides of the girder;
A pair of auxiliary beams installed inside each of the pair of guide beams and slidably coupled to the guide beams;
And the upper and lower sides of the upper flange are moved upward and downward in accordance with the vertical sliding of the auxiliary beam to move the girder upward and downward and at the same time, And a pair of rotation supporting devices capable of receiving the rotation of the girders,
The end support includes:
A pair of second guide beams installed on both sides of the girder;
A pair of second auxiliary beams installed inside and fixed to the pair of second guide beams, respectively;
A pair of second auxiliary beams which are coupled to the inside of each of the pair of second auxiliary beams and which support upper and lower sides of the upper flange to support the girder and which can receive rotation of the girder caused by the warping of the girder A method of manufacturing a prefractional girder comprising:
The method of claim 9,
The rotation support device of the inner support includes:
A bracket coupled to the inside of the auxiliary beam and supporting a lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, an elastic pad coupled to the inside of the auxiliary beam and supporting the upper side of the upper flange, And an elastic pad provided between the elastic pad guide and the upper flange.
The method of claim 9,
The rotation support device of the inner support includes:
A first member coupled to the inside of the auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member such that the first member and the second member are mutually rotatable A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, and a bracket coupled to the inside of the second member and held in contact with the upper side of the upper flange Of prefraction girders.
The method of claim 9,
The rotation support device of the end support includes:
A bracket coupled to the inside of the second auxiliary beam and supporting a lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, And an elastic pad provided between the elastic pad guide and the upper flange.

The method of claim 9,
The rotation support device of the end support includes:
A first member coupled to the inside of the second auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member, A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, and a bracket coupled to the inside of the second member and held in contact with the upper side of the upper flange, Wherein the prefractional girder is made of a steel plate.
Preparing a girder including an upper flange and a lower flange spaced apart from each other, and a abdomen connecting the upper flange and the lower flange;
Wherein an inner support is provided at two points in the center of the girder, a jack is provided on the upper side of the inner support, a count weight is provided on the upper side of the jack, Pressing the girder downward to cause warpage;
Installing a girder to form a lower flange concrete on the girder, installing a reinforcing bar, a sheath tube, and an anchorage on the inner side of the girder, and pouring concrete;
Removing the mold after the concrete is cured and releasing the pressure of the jack,
The inner support includes:
A pair of guide beams installed on both sides of the girder;
A pair of auxiliary beams installed inside each of the pair of guide beams and slidably coupled to the guide beams;
And the upper and lower sides of the upper flange are moved upward and downward in accordance with the vertical sliding of the auxiliary beam to move the girder upward and downward and at the same time, And a pair of rotation supporting devices capable of receiving the rotation of the girders,
The end support includes:
A pair of second guide beams installed on both sides of the girder;
A pair of second auxiliary beams installed inside and fixed to the pair of second guide beams, respectively;
A pair of second auxiliary beams which are coupled to the inside of each of the pair of second auxiliary beams and which support upper and lower sides of the upper flange to support the girder and which can receive rotation of the girder caused by the warping of the girder A method of manufacturing a prefractional girder comprising:
15. The method of claim 14,
The rotation support device of the inner support includes:
A bracket coupled to the inside of the auxiliary beam and supporting a lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, an elastic pad coupled to the inside of the auxiliary beam and supporting the upper side of the upper flange, And an elastic pad provided between the elastic pad guide and the upper flange.
15. The method of claim 14,
The rotation support device of the inner support includes:
A first member coupled to the inside of the auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member such that the first member and the second member are mutually rotatable A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, and a bracket coupled to the inside of the second member and held in contact with the upper side of the upper flange Of prefraction girders.
15. The method of claim 14,
The rotation support device of the end support includes:
A bracket coupled to the inside of the second auxiliary beam and supporting a lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, And an elastic pad provided between the elastic pad guide and the upper flange.
15. The method of claim 14,
The rotation support device of the end support includes:
A first member coupled to the inside of the second auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member, A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, and a bracket coupled to the inside of the second member and held in contact with the upper side of the upper flange, Wherein the prefractional girder is made of a steel plate.
The method according to claim 9 or 14,
Wherein the girder is a honeycomb girder having hexagonal cut-out portions formed along its axial direction in the abdomen.
The method according to claim 9 or 14,
Wherein the girder is formed in advance so that a central portion thereof is convex upwardly or downwardly.
Preparing a girder including an upper flange and a lower flange spaced apart from each other, and a abdomen connecting the upper flange and the lower flange;
An end support is provided at both ends of the girder, and an inner support is provided at two points in the center of the girder. An auxiliary girder is provided on the upper side of the girder, and between the girder and the inner girder And the auxiliary girder is fixed to both the end support and the inner support, and the girder is fixed only to the inner support and is vertically flowable to the end support, So as to generate warpage;
Installing a girder to form a lower flange concrete on the girder, installing a reinforcing bar, a sheath tube, and an anchorage on the inner side of the girder, and pouring concrete;
Removing the mold after the concrete is cured and releasing the pressure of the jack,
The inner support includes:
A pair of second guide beams installed on both sides of the girder;
A pair of second auxiliary beams installed inside and fixed to the pair of second guide beams, respectively;
A pair of second auxiliary beams which are coupled to the inside of each of the pair of second auxiliary beams and which support upper and lower sides of the upper flange to support the girder and which can receive rotation of the girder caused by the warping of the girder A method of manufacturing a prefractional girder comprising:
23. The method of claim 21,
The rotation support device of the inner support includes:
A bracket coupled to the inside of the second auxiliary beam and supporting a lower side of the upper flange, an elastic pad provided between the bracket and the upper flange, And an elastic pad provided between the elastic pad guide and the upper flange.
23. The method of claim 21,
The rotation support device of the inner support includes:
A first member coupled to the inside of the second auxiliary beam, a second member facing the first member, and a second member disposed between the first member and the second member, A bracket coupled to the inside of the second member and held in contact with the lower side of the upper flange, and a bracket coupled to the inside of the second member and held in contact with the upper side of the upper flange, Wherein the prefractional girder is made of a steel plate.

Images