KR101887202B1 - A frame structure of a composite cross section made by tightening a beam and a lower structure into which a camber prestress is introduced, and a construction method thereof - Google Patents

Abstract

The present invention relates to a frame structure of a composite cross section formed by tightening a beam, to which a camber prestress is induced, and a lower structure, and a construction method thereof, which can recover and offset droop and stress by a load, reduce construction costs, and enhance constructability. The frame structure of a composite cross section formed by tightening a beam, to which a camber prestress is induced, and a lower structure includes: a plurality of lower structures, each of which has a reaction bar mounted on an upper portion; a beam having a flexural strengthening plate and a loading bar; a pressurizing jack interposed between the reaction bar and the loading bar; a fixing means mounted between the reaction bar and the loading bar; a strong coupling means for firmly fixing simply fixed beams at both ends; and a concrete composite part formed by concrete poured on a beam shear plane or an upper portion.

Description

Technical Field [0001] The present invention relates to a frame structure of a composite cross-section and a method of constructing the frame structure of the composite cross-section, in which the beam and the lower structure are strengthened by the camber prestress and a construction method thereof construction method thereof}

[0001] The present invention relates to a continuous frame structure and a method of constructing the same, in which a beam and an underframe are intensively joined with an external prestress, and a beam having the force band is installed so as to have a simple support boundary condition in a substructure in which a reaction force band is formed After introducing the camber prestress into the beam using an external prestressing device made up of the above-mentioned resilient band, reaction force band and detachable hydraulic cylinder, the reaction force band and the force band are fixed by the fixing means and the reaction force band of the beam and the lower structure, So that the member force and deflection due to the bottom plate or the slab load can be greatly reduced before the synthesis, and the camber prestress, which is a composite girder or composite slab, is introduced after the bottom plate and the slab are laid thereafter A combination of a beam and a substructure A continuous frame structure of a cross section, and a construction method thereof.

Generally, steel plate girder bridges, steel box girder bridges, preflex girder bridges, and PSC composite girder bridges, which are composite girder bridges, are constructed such that alternating and piercing bridges are constructed, then temporary bridges are installed on the upper surfaces of the alternating bridges and bridge bridges, And the girder is supported by the combined pre-load of the bottom plate or the like by placing the bottom plate which is a combined pre-load after being mounted in a simple supporting state. Therefore, it is necessary to increase the cross section of the girder due to excessive sag and force due to the pre-composite load due to the simple support boundary condition of the mounted girders. As a result, an increase in the construction cost due to the increase of the material, And environmental problems caused by increased carbon dioxide emissions.

Also, since the steel structure composite girder with the upper structure is generally not provided with a prestress, the cross-sectional area of the girder is massive, which causes problems such as lowering of economy and increase of carbon dioxide emissions due to material increase.

In addition, deflection due to a fixed load enlarged by a simple support structure formed before the synthesis is adjusted by a camber manufactured in a fabrication plant. However, when the camber angle change is increased as described above and the bolt fastening force, In the case where the longitudinal camber is not formed, the construction cost and the load increase due to the increase of the concrete amount in the case where the longitudinal linear shape causes the decrease of the load bearing capacity.

In addition, when introducing the prestress into the girder through PS wire or prefabrication, additional material is required because PS wire, separate fixing device and connection device, and massive pre-refraction device are needed. There is a problem such as an increase in air.

On the other hand, a conventional slab bridge, a ramen bridge, and the like should be installed on the lower surface of the slab in order to install the upper structural slab. Therefore, there are problems such as an increase in construction cost due to an increase in construction materials, a decrease in construction stability due to an increase in manpower input, and an increase in air.

Also, the slab bridges and the bridges are resistant to all external forces after the composite without any pre- and post-collision through the construction process that supports the upper structure as a whole without any prestress, If the accuracy of the camber is lowered due to the lowering of the economical efficiency and the camber is adjusted to the deflection due to the load, the design linearity is deteriorated due to the lack of design camber, There is a problem that the appearance is reduced.

Registered Patent No. 10-1072259

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above problems and to solve the above problems in the prior art, and an object of the present invention is to provide an apparatus and a method for installing a beam having a force bar on a lower structure having a reaction force band, A camber and a prestress are formed in the beam by using a prestressing device, and then the reaction force band and the force band are fixed by the fixing means, and the reaction force band of the beam and the lower structure is strengthened to form both end information, The camber prestress which can reduce the member force and deflection caused by the load greatly strengthens the beam and the lower structure, so that deflection and stress due to the load before and after the composite can be restored and offset, and additionally when the camber and prestress are introduced By minimizing the amount of material generated and reducing the cost and And a concrete structure in which a beam and a lower structure having a camber prestress introduced thereinto are formed by reinforcing a bottom plate and a slab to form a composite girder or a composite slab, and a construction method thereof.

According to an aspect of the present invention, there is provided an image forming apparatus including: a plurality of lower structures spaced apart from each other by a predetermined distance, A beam provided on both sides of the reaction force band adjacent to the reaction force band so as to be supported on both sides thereof and having a bending stiffening plate to be coupled with the reaction force band and having a force bar to be positioned opposite to the reaction force band; A pressing jack which is interposed between the reaction force band and the force band and presses the force band toward the inward direction of the beam in a horizontal direction in a state where the force band is supported by the reaction force band so that a prestress and a camber are formed in the beam, Fixing means provided between the pressing bar and the reaction force bar so as to maintain the camber state in the beam even after the pressing jack is removed; A stronger means for fixing the beam and the reaction force band to each other by fixing the beam and the reaction force band so that a simple fixed beam is fixed at both ends; And a concrete composing unit in which concrete is placed on the beam front surface or the top of the beam so that the reaction force band and the force band are buried.

The reaction force band may include a reaction force band body installed to protrude from an upper portion of the lower structure; And a cap plate installed on an upper portion of the reaction force body to allow the beam to be seated, and a camber prestress is introduced into the beam, and then the beam penetrates the beam.

Further, the reaction force body is made of a steel material, and the cap plate is a metal plate coupled to an upper portion of the reaction force body.

The reaction force body may be made of a concrete material. The cap plate may include an upper plate attached to the upper surface of the reaction force body and a vertical plate protruding vertically from the lower plate to be embedded in the reaction force body, And a bolt and a nut for connecting the lower plates and fixing the cap plate to the reaction force without being separated from the body.

Further, the projecting means may include a vertical portion coupled to the stiffening plate of the beam, and a horizontal portion extending horizontally from one end of the vertical portion and being in close contact with a lower surface of the lower portion of the beam. A vertical part coupled to the side of the reaction force band and a horizontal part extending horizontally at one end of the vertical part and tightly fitted to the other lower side surface of the beam and fastened to the horizontal part of the beam- And a cleansing cleat.

The projecting means may include a vertical portion coupled to the bent stiffening plate of the beam and a vertical portion extending horizontally from one end of the vertical portion and being in close contact with a lower side surface of the beam, ; And an anchor bolt having one end embedded in the reaction force body and the other end exposed through an upper plate of the cap plate to an upper portion of the reaction force band and fastened to the beam through a fastening member.

When the reaction force unit is a steel member, the reaction force unit is installed so as to be integrally connected to the upper end of the single piece pile installed in the lower structure, so that the reaction force band is unshakable.

In the meantime, the present invention provides a method for constructing a substructure in which two or more substructures are constructed so as to meet designed intervals, and a reaction force band is embedded in an upper portion of the substructure; A beam installation step of installing a beam so that both ends of the beam have a simple supporting boundary condition on a reaction force band of a neighboring lower structure of the lower structure, wherein a beam is installed on both ends of the beam so as to face the reaction force band; A camber prestress introducing step of introducing a camber prestress in an upward direction into the beam by pressing the pressing rod toward the center of the beam by operating the pressing jack after installing a pressing jack between the reaction force band and the pressing band; A camber holding step of providing a fixing means for supporting between the reaction force band and the force band so as to maintain the camber prestress introduced into the beam and then removing the pressure jack; A beam and a reaction force vs. strongening step for causing the beam and the reaction force band to be stronger through the stronger means so that the beam has both end support boundary conditions; Placing the concrete so that the pressing force is embedded, so that the pressing force is unified with the lower structure; And forming a concrete composite part by placing concrete in the beams.

In addition, when the lower structure is alternated in the beam installation step, the beam is installed such that the end portion protrudes partly outward of the lower structure.

Also, in the concrete composite forming step, the bottom plate is formed by placing concrete on the beam.

Also, in the concrete composite forming step, the slab is formed by pouring the concrete so that the beam is completely embedded.

As described above, according to the present invention, by operating a stroke on a force bar provided on a beam with a reaction force band as a fulcrum in a beam installed to be simply supported on a lower structure, eccentric moments are generated by eccentricity of the center of the neutral axis of the beam, And prestress are introduced, and it is formed by the form of both end information and the ramen, that is, the form of the frame structure, by which the force and the deflection due to the bottom plate or the slab load are greatly reduced before the synthesis, It is effective.

In addition, by introducing a prestress into the upper structure, the section of the upper structure is made slim by offsetting the stress caused by the hysteresis, which is advantageous not only in economic efficiency but also in securing the building limit.

In addition, since deflection is greatly reduced by forming an irregular structural system such as both ends information before synthesis, it is a method having excellent workability by improving the problem that may occur when the bolt tightening force is lowered due to reduction of camber produced.

In addition, by introducing the prestress by external prestressing, PS wire insertion, coupler connection and grouting work are omitted in the field, and it is a construction method which has the effect of shortening the construction time and improving manpower and reducing labor requirement and construction safety.

Further, in order to place a slab such as a slab bridge or a ramen bridges, the conventional method does not install the bridges on the bottom surface of the slab, but the present invention secures the camber on the pre-combined beam and then hangs the form on the beam, It is a construction method that has the effect of reduction of construction costs, reduction of construction stability due to decrease of manpower input, and shortening of construction time.

In addition, in the process of mounting the beam on the lower structure, the beams are partially protruded from the point of the bridge, thereby reducing the deflection and moment of the span of the span and decreasing the stress generated in the diagonal direction of the span end There is no need to reinforce a reinforcing plate or the like, thereby improving workability and economical efficiency.

1 is an exemplary view showing a state in which a reaction force band is installed in a lower structure according to the present invention,
2 is a view showing a state where a beam is installed so as to have a simple support boundary condition in a reaction force band according to the present invention,
3 is a view illustrating a process of installing a pressure jack between a reaction force band and a force band of a beam according to the present invention and introducing a camber prestress into the beam,
FIG. 4 is a view illustrating a process of providing a fixing means between a reaction force band and a force band according to the present invention and removing the pressure jacks so that the introduction state of the camber prestress is maintained in the beam.
5 is an illustration showing a prestressing force, a camber and an eccentric moment acting on a beam introduced into a camber prestress according to the present invention,
FIG. 6 is an exemplary view showing a state in which a beam and a reaction force band introduced with the camber prestress according to the present invention are rigidified by using a stronger means
FIG. 7 is a view illustrating a process of placing a concrete so that a reaction force band and a force band according to the present invention are embedded, and forming a bottom plate to form a frame structure of a composite cross section by placing concrete in an upper section of the beam.
FIG. 8 is a view showing another reaction force band composed of elements for simple support and strength when the reaction force unit according to the present invention is concrete, FIG.
FIG. 9 is an exemplary view showing a state in which a beam and a reaction force band in which a camber prestress is introduced when the reaction force unit according to the present invention is a concrete member is rigid using a force means;
10 is a view illustrating a process of forming a frame structure of a composite cross section by placing a concrete so that a reaction force band and a force band according to the present invention are embedded,
FIG. 11 is a view showing an example of a frame structure of a composite section having a short span shape formed by severing a beam and a lower structure by introducing a camber prestress according to the present invention, FIG.
12 is an exemplary view showing a state in which a reaction force band according to the present invention is integrally connected to a support frame file of a lower structure and is unshielded;
13 is a plan view showing a state in which connection means for coupling with a reaction force band is formed so as to be connected to a plurality of files in a supporting single file of a lower structure according to the present invention,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 2 is a view showing a state in which a beam is installed so as to have a simple support boundary condition in a reaction force band according to the present invention. FIG. 3 is a cross- FIG. 4 is a view showing a process of installing a pressing jack between a reaction force band and a force band of a beam according to the present invention and introducing a camber prestress into the beam, FIG. 4 is a view showing a case where a fixing means is provided between the reaction force band and the force band according to the present invention FIG. 5 is a view showing an example of a prestressing force acting on a beam introduced with a camber prestress according to the present invention, a camber and an eccentric moment, and FIG. 6 is a view showing an example in which a beam and a reaction force band introduced with a camber prestress according to the present invention are in a rigid state using a stronger means, FIG. 8 is a view showing a process of forming a frame structure of a composite section by placing a concrete in a top section of a beam and placing a bottom plate in the upper section of the beam so that a force band and a force band are embedded. FIG. 9 is a view showing another example of a reaction force band composed of elements for supporting and steeping, and FIG. 9 is a view showing a state in which a beam and a reaction force band in which a camber prestress is introduced when a reaction force unit according to the present invention is a concrete member, FIG. 10 is a view showing a process of casting a concrete so that a reaction force band and a force band according to the present invention are embedded, and forming a frame structure of a composite cross section by pouring concrete into a beam front face, The present invention relates to a composite cross section of a short span shape formed by tightening a beam and a lower structure, Fig. 12 is an exemplary view showing a state in which a reaction force band according to the present invention is integrally connected to a supporting unit file of a lower structure to unshrunk communication, Fig. 13 is a view showing an example of a supporting unit file In which a connecting means for coupling with a reaction force band is formed so as to be connected to a plurality of files,

As shown in the drawings, the composite cross-section frame structure according to the present invention includes a lower structure 100 having a reaction force band 110 disposed at a predetermined distance apart from the reaction force band 110 and a reaction force band 110 A beam 200 installed at the upper end of the reaction force band 110 so that both ends thereof are in a state of simple support boundary condition and a beam 200 interposed between the reaction force band 110 and the force band 230 and supported by the reaction force band 110, A pressing jack 300 is formed to press the beam 230 horizontally toward the center of the beam so that a prestress and a camber are formed in the beam 200 and a pressing jack 300 is formed between the pressing bar 230 and the reaction force band 110 A fixing unit 400 that is installed in the beam 200 to maintain the state in which the camber prestress is introduced into the beam 200 even after the pressing jack 300 is removed, (500) for fixing the beam (200) at both ends, and a reaction force unit And a concrete composite part 600 in which concrete is placed on the front end or upper part of the beam 200 so that the reinforcing part 230 and the reinforcing part 230 are embedded.

The lower structure 100 may be made of a pair of opposing faces as shown in Fig. 11, or alternatively a pair of alternating faces facing each other as shown in Figs. 1 to 10 and at least one pier provided between the alternations And can be arranged in a short span or multi-span structure.

The reaction force band 110 includes a reaction force band body 120 formed on the upper part of the lower structure 100 and a cap plate 120 mounted on the reaction force band body 120 to allow the beam 200 to be seated and coupled. (130).

The reaction force body 120 may be made of a steel material or a concrete material. In the case of a steel material, the first and second flanges 121 and 121, And a web 123 connecting the first flange 121 and the second flange 122 to each other. In this case, the cap plate 130 may be welded to the upper surface of the reaction force body 120, and the reaction force body 120 may be formed in various shapes such as a box or channel shape.

Meanwhile, the cap plate 130 when the reaction force body 120 is made of a concrete material includes an upper plate 131 attached to the upper surface of the reaction force body 120 as shown in FIGS. 8 and 9, A pair of lower plates 132 which are vertically protruded from the lower portion of the body 131 and are embedded in the reaction force body 120 or fitted to both sides of the upper surface of the reaction force body 120, And a connecting member 133 that connects the cap plate 130 and the cap plate 130 so that the cap plate 130 can be firmly fixed without being separated from the reaction force of the body 120. The connecting member 133 may be composed of a bolt and a nut.

The beam 200 includes a beam body 210 installed on the reaction force platform 110 of the lower structure 100 at a predetermined interval so that both ends of the beam body 210 are in a simple support boundary condition, A beam reinforcing plate 220 attached to a face corresponding to the reaction force position on both sides of the beam body 210 so that the beam body 210 can be coupled to the reaction force band 110, And is horizontally disposed inside the center of the beam body 210 through a press jack 300 installed on the reaction force band 110 and positioned to face the reaction force band 110. [ So that the camber prestress can be introduced into the beam body 210. [0033]

After the camber prestress is introduced into the beam body 210, the beam is removed from the press jack 300. At this time, even if the press jack 300 is removed, The fixing unit 400 is installed between the reaction force unit 230 and the reaction force unit 110 so that the reaction force unit 110 is tightened against the reaction force unit 110 before being combined with the concrete composition unit 600 to form a frame structure.

The beam body 210 includes a first flange 211 and a second flange 212 positioned to face each other and a web 213 connecting the first flange 211 and the second flange 212 Can be.

The upper and lower ends of the bending stiffening plate 220 are attached to the first flange 211 and the second flange 212 and one side is attached to the web 213.

The bending stiffening plate 220 may be provided on at least two faces of the beam body 210 corresponding to the positions of the two reaction force bands 110 so as to reinforce the rigidity of the beam body 210, 500 so that the upper structure and the lower structure resist the flexural strength as the frame structure is formed by the rigid structure.

Preferably, the force rest 230 is attached to the beam body 210 before the beam body 210 is manufactured. The pressing bar 230 includes a first flange 231 and a second flange 232 facing each other and a web 233 connecting the first flange 231 and the second flange 232 .

The beam 200 thus constructed is mounted on the reaction force band 110 so as to have a simple support boundary condition so that the beam 200 is transferred to the beam 200 using the pressing jack 300 provided between the reaction force band 110 and the force band 230. [ , The camber prestress can be easily introduced through the inner side of the span in the horizontal direction inside the span, so that the stress due to the external force can be canceled and the camber can be adjusted through it, It is possible to reduce the member force and sagging due to the bottom plate or the slab load before synthesis by forming the frame structure in the form of both end information and the ramen.

Meanwhile, the beam 200 is installed such that the end of the beam 200 partially protrudes outside the lower structure 100 when the lower structure 100 alternates.

As described above, the beam 200 is installed in the form of an inner beam so as to partially protrude to the outer side of the lower structure 100, so that it is unnecessary to further attach the beam to the beam due to excessive stress generated at the right- And it is possible to improve the structural stability, such as the load applied to the bolts, which reduces the bending moment and deflection at the center span.

2, in order to be coupled to the reaction force band 110 under a simple support boundary condition, the beam is attached to the second flange 212 on the roller fixing end and the cap plate 130 to be brought into contact with the second flange 212 Shaped bolt holes 124 and 134 are formed and then fastened through bolts and nuts, and a normal bolt hole is formed and fixed to the hinge fixing end.

8, an anchor bolt 523 is embedded in the reaction force band 110 in advance so as to be coupled to the reaction force band 110 in a simple support boundary condition, and the anchor bolt A bolt hole 134 is formed in the cap plate 130 to be in contact with the second flange 212 and the second flange 212 at the roller fixing end in a position corresponding to the first flange 212 and the second flange 212, A normal bolt hole is formed and fixed to the hinge fixing end.

In other words, since the beam is fitted to the simple support boundary condition, the camber prestress can be introduced into the beam 200 when the pressing bar 230 is pressed through the pressing jack 300.

The pressure jack 300 may use various types of pressure jacks 300 such as a conventional hydraulic jack or a pneumatic jack.

4, the fixing unit 400 is coupled to the reaction force band 110 at one end thereof, and the pressing member 230 and the reaction force band 230 coupled to the force band 230, 110 are kept constant.

1, 2, 3, 4, 6, and 7, the fixing means 400 when the reaction force band 110 is a steel member may be fixed to the second flange 122 of the reaction force band 110, The bolts 410 are fastened to the first flange 231 of the first and second flanges 231 and 230 and the bolts 410 and are pressed against the reaction force bar 110 and the force bar 230, And a plurality of nuts 420 that maintain the spacing of the base 230.

8 and 9, the fixing means 400 when the reaction force body 120 is a concrete material includes a socket 430 installed to be embedded in the reaction force body 120 in advance, A bolt 410 fastened to the socket 430 through a first flange 231 of the bolt 410 and a bolt 410 fastened to the bolt 410 to be fastened to the first flange of the bolt 230, And a plurality of nuts 420 for maintaining the gap between the engaging pieces 230.

The fixing means 400 for holding the gap between the pressing member 230 and the reaction force mount 110 in a state where the pressing force is applied is fixed by using the bolts 410 and the nuts 420, It is not limited to the method that can be restrained by a forward load jack including a jack.

After the pressurizing jack 300 is removed by using the fixing means 400 as described above, the introduction of the camber prestress of the beam is maintained and then the concrete is poured so that the reaction force band 110 and the force band 230 are completely embedded. So that the reaction force band 110 and the force band 230 can be integrated into the lower structure 100.

Meanwhile, the derricking means 500 may be constructed such that the beam 200 coupled to the reaction force platform 110 is completely pulled into the reaction force platform 110 by the simple supporting boundary condition, and the beam 200 is fixed to both ends of the frame structure, .

6, the derricking means 500 includes a beam clearing cleat 510 coupled to the beam 200, a reaction clearing cleat 520 coupled to the reaction beam 110, and a beam cleat cleat 510, And a fastening member 530 for fastening the beam 200 and the reaction force band 110 by tightening and integrating the reaction cleat cleat 520.

The beam clevis cleat 510 includes a vertical portion 511 coupled to the stiffening plate 220 of the beam 200 and a second portion 511 extending horizontally at one end of the vertical portion 511, And a horizontal portion 512 which is in close contact with one side face of the flange 212.

6, when the reaction force band 110 is a steel material, the vertical cleat cleats 520 are coupled to the first flanges 121 and the second flanges 122 of the reaction force band 110, And a horizontal part 522 horizontally extending from one end of the vertical part 521 and closely contacting the other side of the second flange 212 of the beam 200.

The beam clevis cleat 510 and the reaction clevis cleat cleat 520 are coupled to the beam 200 and the reaction force balancer 110 through bolts and nuts as shown in the figure and are fastened together with bolts 531 and nuts 532 And the horizontal portion is fastened through the member 530 so that the beam and the reaction force band 110 are strong.

The beam cleat cleat 510 in the case where the reaction force versus the body 120 is made of concrete is constructed in the same manner as the beam cleat cleat 510 in the case where the reaction force versus the body 120 is steel, 8 and 9, one end of the reaction force is buried in the body 120 and the other end of the reaction force is penetrated through the cap plate 130 and exposed to the upper part of the reaction force band and is passed through the second flange 212 of the beam 200 And an anchor bolt 523 which is coupled to the anchor bolt 523 and is fastened to the second flange 212 of the beam 200 so that the beam 200 and the reaction force band 110 are integrated with each other, ). The fastening member may be a conventional nut fastened to the anchor bolt 523.

On the other hand, when the lower structure 100 is a pier, two beams 200 installed in the longitudinal direction of the bridge are installed on the upper portion of the reaction force platform 110 in a state of being separated from each other. At this time, the reaction force band 110 is buried to be positioned at the center of the lower structure 100, and the neighboring beam 200 is installed in a state where the beam 200 is mounted for a part with respect to the upper center of the reaction force band 110.

After the camber prestress is introduced, the beams 200 are tightly coupled to the reaction force band 110 and are coupled to the adjacent beam 200 by the joint member 240 which is usually used,

The coupling member 240 is installed on the upper and lower surfaces of the first flange 211 of the neighboring beams 200 A first engaging plate 241 and a second engaging plate 242 which are fastened by bolts and nuts and a third engaging plate 242 which is provided to connect the web 213 of the neighboring beams 200 and fastened by bolts and nuts, (243).

Meanwhile, as shown in FIG. 7, the concrete composing unit 600 may be constructed by placing a concrete on the upper surface of the beam 200 and forming a bottom plate 620 in a state where a reaction force band and a force band are embedded.

Also, as shown in FIG. 10, the slab 610 may be formed by placing the concrete in the beam so that the beam 200 is completely embedded.

As described above, the present invention forms a composite cross-section through the concrete composite part 600 to form a multi-span frame structure by completely integrating the upper and lower structures.

The construction of the multi-span frame structure of the present invention having the composite section of the present invention can be realized by first constructing a substructure, installing a beam, installing a camber prestress, maintaining a camber, A large embedding step, and a concrete composite forming step.

The substructure construction step is to construct the substructure 100 such that two or more substructures 100 are constructed so as to fit the designed spacing, and a reaction force band protrudes to the upper part of the substructure 100.

In the beam installation step, both ends of the beam 200 are mounted on the reaction force band 110 of the neighboring substructure 100. At this time, the beam 200 is installed so as to have a simple support boundary condition so that one end is hinged to the reaction force band 110 and the other end is fixed to the roller.

In addition, in the process of manufacturing the beam 200, a force bar 230 is installed at a lower portion of the beam 200 so that the force bar 230 is positioned facing the reaction force bar 110 when the beam is mounted.

As a result, the camber prestress can be introduced into the beam 200 when the beam 200 is pressed through the press jack 300 in the step of introducing the camber prestress.

In addition, when the lower structure 100 is alternated, the beam 200 is extended so as to partially protrude to the outside of the alternating portion, thereby reducing deflection and moment of the span of the span, It is not necessary to reinforce the reinforcement plate or the like by reducing the stress, so that the workability and the economical efficiency can be improved.

In the camber prestress introduction step, a pressure jack 300 is installed between the reaction force band 110 and the force band 230, and then the pressure jack 300 is operated to move the force band 230 to the beam body 210, So that the beam 200 introduces the camber prestress in the upward direction.

In the step of introducing the camber prestress, the camber prestress is introduced into the beam by simply pressing the force bar 230 after the press jack 300 is installed between the reaction force bar 110 and the force bar 230, The introduction process of the camber prestress can be performed very simply and quickly, and the workability is greatly improved.

Also, by introducing the camber prestress into the beam 200, the deflection and the stress can be recovered and canceled by the external force.

Meanwhile, in the camber holding step, the fixing unit 400 may be installed between the pressing bar 230 and the reaction bar 110 to maintain a gap between the reaction bar 110 and the pressing bar 230, The camber prestress introduced into the beam 200 is not released.

The beam and the reaction force versus the warp step may be performed such that the beam 200 and the lower structure 100 are tightened by using the stronger means 500 so that the beam 200 installed to have a simple boundary support condition has both ends support or a laminate structure boundary condition .

Meanwhile, the pressing force is a step of pouring the concrete so that the pressing bar 230, which is exposed to the outside, is embedded so that the pressing bar 230 is integrated with the bottom structure 100.

Meanwhile, the concrete composing part forming step is a process of forming a concrete composing part 600 by placing concrete on the front end or upper part of the beam 200.

7, the concrete composite part forming step may include forming a bottom plate 620 by placing concrete on the upper surface of the beam 200 in a state where the reaction force band 110 and the force band 230 are embedded, The slab 610 can be formed by placing the concrete in the beam 200 to completely fill the beam 200 as shown in FIG.

In the present invention, a composite section is formed through a concrete composite section 600 to form a multi-span frame structure in which the upper and lower structures are completely integrated.

According to the present invention configured as described above, the camber prestress is introduced in a state where the beam 200 is simply fixed before the synthesis of the concrete composite part 600, and then the beam 200 is tightened with the reaction force band 110, It is possible to recover and cancel the deflection and the stress caused by the load of the load.

FIG. 12 is an exemplary view showing a state in which a reaction force band according to the present invention is integrally connected to a support single file of a lower structure, and FIG. 13 is a view showing a state where a reaction force band When the reaction force band 110 is made of steel, the single piece file 140 installed in the lower structure 100, as shown in FIG. 12, The reaction force band 110 may be integrally connected to the upper end of the body 110 via the connection unit 150 so as to communicate with the reaction force band.

The connection unit 150 includes a reaction force connection unit 151 installed on the reaction force band and a file connection unit 152 installed on the file 140. The reaction force connection unit 151 and the file The connection part 152 is fastened and connected through bolts and nuts to connect the reaction force band 110 and the file 140.

13, the file connection unit 152 may be configured to connect a plurality of files 140 installed in the lower structure 100 to each other.

According to the present invention configured as described above, by operating the stroke on the force bar provided on the beam with the reaction force band as a fulcrum, the eccentric moment generated by the eccentricity of the center of the neutral axis of the beam causes the camber and the prestress So that it is possible to restrain and compensate deflection and stress due to the load before and after the synthesis.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

(100): substructure (110): reaction force band
(120): reaction force body (121): first flange
(122): second flange (123): web
(124): a slotted bolt hole (130): a cap
(131): upper plate (132): lower plate
(133): connecting member (134): slotted bolt hole
(140): single file (150): connection means
(151): Reactive force substitute connection part (152): File connection part
(200): beam (210): beam body
(211): first flange (212): second flange
(213): web (220): a stiffening plate
(230): a pressing member (231): a first flange
(232): second flange (233): web
(240): engaging member (241): first engaging plate
(242): second coupling plate (243): second coupling plate
(300): pressure jack (400): fixing means
(410): Bolt (420): Nut
(430): Socket (500): Grounding means
(510): Forge clevis cleat 511: Vertical portion
(512): horizontal portion (520): force resisting force cleat
(521): vertical part (522): horizontal part
(523): anchor bolt (530): fastening member
(531): Bolt (532): Nut
(600): Concrete composing part (610): Slab
(620): bottom plate

Claims (11)

delete delete delete delete A plurality of lower structures positioned so as to be spaced apart from each other at predetermined intervals,
A beam provided on both sides of the reaction force band adjacent to the reaction force band so as to be supported on both sides thereof and having a bending stiffening plate to be coupled with the reaction force band and having a force bar to be positioned opposite to the reaction force band;
A pressing jack which is interposed between the reaction force band and the force band and is supported by the reaction force band, presses the force band inward in the span toward the horizontal direction of the beam to form a prestress and a camber in the beam,
Fixing means provided between the pressing bar and the reaction force bar so as to maintain the camber state in the beam even after the pressing jack is removed;
A stronger means for fixing the beam and the reaction force band to each other by fixing the beam and the reaction force band so that a simple fixed beam is fixed at both ends;
A concrete composing unit having concrete placed on a beam front surface or an upper part of the beam so that the reaction force band and the force band are embedded; ≪ / RTI >
The reaction force band is composed of a reaction force band body installed to protrude to the upper part of the lower structure and a cap plate installed on the reaction force band body to be able to seat the beam and to which a camber prestress is introduced into the beam, However,
Wherein the reaction force body is made of a steel material and the cap plate is made of a metal plate coupled to an upper portion of the reaction force body,
Wherein the projecting means comprises a vertical portion coupled to the stiffening plate of the beam and a vertical portion extending horizontally at one end of the vertical portion and being in close contact with a lower side of the beam, And a vertical portion extending horizontally at one end of the vertical portion and closely contacting the lower surface of the lower portion of the beam and being coupled to the horizontal portion of the beam cleat cleat via bolts and nuts, Wherein the beam and the lower structure are rigidly joined to each other by a camber prestress.
A plurality of lower structures positioned so as to be spaced apart from each other at predetermined intervals,
A beam provided on both sides of the reaction force band adjacent to the reaction force band so as to be supported on both sides thereof and having a bending stiffening plate to be coupled with the reaction force band and having a force bar to be positioned opposite to the reaction force band;
A pressing jack which is interposed between the reaction force band and the force band and is supported by the reaction force band, presses the force band inward in the span toward the horizontal direction of the beam to form a prestress and a camber in the beam,
Fixing means provided between the pressing bar and the reaction force bar so as to maintain the camber state in the beam even after the pressing jack is removed;
A stronger means for fixing the beam and the reaction force band to each other by fixing the beam and the reaction force band so that a simple fixed beam is fixed at both ends;
A concrete composing unit having concrete placed on a beam front surface or an upper part of the beam so that the reaction force band and the force band are embedded; ≪ / RTI >
The reaction force band is composed of a reaction force band body installed to protrude to the upper part of the lower structure and a cap plate installed on the reaction force band body to be able to seat the beam and to which a camber prestress is introduced into the beam, However,
The reaction force body is made of a concrete material, and the cap plate includes an upper plate attached to the upper surface of the reaction force body, and a reaction plate which is vertically protruded from the lower plate and embedded in the reaction force body, And a bolt and a nut for connecting the lower plates and fixing the cap plate to the reaction force without being separated from the body.
Wherein the projecting means comprises a vertical portion coupled to the stiffening plate of the beam and a beam clearing cleat extending horizontally at one end of the vertical portion and in contact with the lower surface of the beam and coupled to the top plate of the cap plate, And an anchor bolt, one end of which is embedded in the reaction force body and the other end of which is exposed through the upper plate of the cap plate and exposed to the upper side of the reaction force band and fastened to the beam through the fastening member. And a frame structure of a composite section formed by tightly joining the beam and the lower structure. 6. The method of claim 5,
Wherein when the reaction force unit is a steel member, the reaction force unit is installed so as to be integrally connected to the upper end of the single pile file installed in the lower structure, so that the camber prestressed beam and the lower structure are tightened. Structure. A substructure construction step of constructing a substructure in such a manner that two or more substructures are constructed so as to meet the designed spacing, and a reaction force band is embedded in an upper part of the substructure;
A beam is installed on both sides of the beam so as to have a simple supporting boundary condition on the reaction force band of the neighboring lower structure of the lower structure, and a bending stiffening plate is provided on both sides of the beam, A beam mounting step for positioning the base so as to face the reaction force band;
A camber prestress introducing step of introducing a camber prestress in an upward direction into the beam by pressing the pressing rod toward the center of the beam by operating the pressing jack after installing a pressing jack between the reaction force band and the pressing band;
A camber holding step of providing a fixing means for supporting between the reaction force band and the force band so as to maintain the camber prestress introduced into the beam and then removing the pressure jack;
A vertical portion coupled to a side surface of the reaction force band, a vertical portion coupled to a bent stiffening plate of the beam, and a horizontal portion extending horizontally at one side of the vertical portion and closely contacting a lower side surface of the beam, And a vertical portion extending horizontally at one end of the vertical portion and closely contacting the lower surface of the lower portion of the beam and fastened to the horizontal portion of the beam cleat cleat via bolts and nuts, A beam and a reaction force versus a strongening step to force the beam and the reaction force band so that the beam has both end support boundary conditions;
Placing the concrete so that the pressing force is embedded, so that the pressing force is unified with the lower structure;
And forming a concrete composite part by pouring concrete into the beams. The method for constructing a frame structure of a composite cross-section, wherein the beam and the lower structure are strengthened by the introduction of the camber prestress. 9. The method of claim 8,
Wherein when the lower structure is alternated in the beam installation step, the beam is installed so that the end portion protrudes partly outward of the lower structure. The beam structure according to claim 1, Construction method. 9. The method of claim 8,
In the concrete composite forming step,
And a bottom plate is formed by placing concrete on top of the beam. A method of constructing a frame structure of a composite cross-section, wherein the beam and the substructure are tightened with a beam having the camber prestress introduced therein. 9. The method of claim 8,
In the concrete composite forming step,
Wherein the slab is formed by pouring the concrete so that the beam is completely buried, wherein the slab is formed by tightening the beam and the substructure into which the camber prestress is introduced.

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