KR20200056062A - Long span structure and construction method using bending beam - Google Patents

Abstract

The present invention relates to a long span structure which is to secure a large non-pillar space and build a slab structure with an iron beam maintained to be bent from the center towards an upper side for corresponding to a stress shape given to a beam member in a building structure such that the beam is prevented from sagging with a long non-pillar interval (first resistance), and even if sagging occurs on the center of the iron beam constructed being bent by a load applied to the slab afterwards, the center of the iron beam does not sag downwards but only becomes flat (second resistance), thereby not leading to a reduced durability of the building. The long span structure construction method using a bending iron beam comprises: a step (a) of coupling the iron beam to a portion between pillar members; a step (b) of installing a hydraulic jack on a lower side of the iron beam; a step (c) of pushing the iron beam upwards by using the hydraulic jack to curve the iron beam upwards so as to make the center the peak point to correspond to the stress shape given to the beam member in the building structure; a step (d) of installing a supporting post with an adjustable height on a lower side of the iron beam while maintaining the loading status of the hydraulic jack, controlling the height of the supporting post in accordance with the curved shape of the iron beam to install the supporting post to maintain the curved shape by supporting the iron beam, and recollecting the hydraulic jack; and a step (e) of building the slab structure on an upper side of the iron beam, and releasing the supporting post.

Description

Long span structure and construction method using bending beam

The present invention relates to a long span structure for securing a large space of a pillar, and is constructed by allowing a slab structure to be constructed in a state in which a steel beam is bent upward from the center to correspond to a stress form received by a beam member in a building structure. Prevents the deflection of the beam in the state where the main long span is secured (primary resistance), and even if the deflection occurs in the center of the steel beam constructed in the bending state by the load applied to the slab later, it does not sag downward but will be flattened. Since it is only (secondary resistance), it relates to a long span structure and a construction method of a long span structure that does not lead to a decrease in durability of a building.

The long span structure has been mainly applied to bridges and has been developed, but the long span structure is applied to various buildings that minimize the pillars, such as parking lots, factories, distribution warehouses, gymnasiums, and where indoor space utilization is required.

The problem of the long span structure is that the bending moment acting on the center and both ends and the shearing force acting on both ends increase in proportion to the span, as shown in FIG. 1. Therefore, a truss structure that can distribute loads to various members in order to secure a long span of the pillar, a pre-stress structure that reduces the final load by pre-introducing the load applied to the beam in the reverse direction, and the steel frame constituting the beam Reinforcement structures, etc., in which various forms and reinforcing members have been varied, have been applied individually or in combination.

1. Registered Patent 10-0926667 "Self-propelled parking facility using inter-field beam" 2. Registered Patent 10-1628343 "Synthetic beam with reinforced truss rigidity" 3. Registered Patent 10-1676707 "Column-beam connection structure" 4. Registered Patent 10-0352646 "Reinforcement method for enhancing the load carrying capacity of structures using elastic beams" 5. Registered Patent 10-0733609 "A method for enhancing the load carrying capacity of concrete structures using the rise of steel" 5. Registered Patent 10-1595736 "Support structure installation structure"

An object of the present invention is to provide a method of bending a steel frame beam and maintaining a curved state, thereby securing constructability and economy, and ensuring a load-bearing capacity of a long span structure.

The present invention is "steel beams curved at a bending rate so as to correspond to the stress form received by the center and both ends of the structural structure beam member; Beam-end concrete that is coated on both ends of the steel beam to maintain the curved state of the end; And a slab concrete built on the upper portion of the steel frame beam to maintain a curved state of the central portion. It provides a long-span structure configured to resist the deflection and load of the beam, including.

The steel beam may be applied to a center member and a side member, wherein the side member has a larger longitudinal section than the center member.

In addition, the present invention "(a) coupling steel beams between pillar members; (c) disposing a hydraulic jack under the steel frame beam; (c) pushing up the steel beams with the hydraulic jacks, and bending the steel beams at a bending rate to correspond to the stress forms received by the central and both ends of the beam member of the building structure; (d) While maintaining the pressing force of the hydraulic jack, a copper bar whose height is adjusted is installed at a lower portion of the steel beam, and the copper bar is curved by supporting the steel beam by adjusting the height of the copper bar according to the curved shape of the steel beam. Installing to maintain the shape, and recovering the hydraulic jack; And (e) covering the beam-end concrete at the end of the steel frame beam, constructing slab concrete on the upper part, and dismantling the copper bar; A method of constructing a long span structure including the same is provided.

According to the present invention has the following effects.

1. It is manufactured to be bent upward from the center, and it can first resist resistance to deflection of a beam while securing a long span of a pole by a steel beam that maintains its shape. The durability of the building is not deteriorated because it does not sag downward and is flattened.

2. Since it is possible to utilize the copper bar required for the construction of the slab structure as a means for maintaining the curved shape of the steel frame beam, it is possible to omit the application of a separate process or a separate means for maintaining the curved shape of the steel frame beam.

3. The compressive force of the lower part of the beam-coated concrete covered at the end of the steel beam and the compressive force of the slab concrete built on the upper part of the steel beam is not only a means for maintaining the curved state of the steel beam, but also as a pre-stress to the steel beam. It acts to share the dead load applied to the steel beam, and plays a role against the deflection of the steel beam.

4. By combining a side member having a large cross-sectional area on both sides of a center member having a small cross-sectional area, a steel cross-section of the cross-section can be constructed, thereby reducing the weight of the steel beam and enhancing the bending moment and shear resistance of the steel beam end.

[Figure 1] shows the distribution of the bending moment and shear force that the beam member receives in the building structure.
[Fig. 2] shows a state in which a steel beam is coupled between pillar members.
[Figure 3] shows a state in which the hydraulic jack is disposed under the steel beam, and the steel beam is pushed up by the hydraulic jack.
[Figure 4], while maintaining the force of the hydraulic jack, the height of the steel bar is installed on the lower part of the steel bar, and the height of the copper bar is adjusted according to the curved shape of the steel bar to support the steel bar. It shows the process of installing to maintain the curved shape.
5 shows a long span structure in which beam-end concrete and slab concrete are constructed according to the present invention.
[Figure 6] shows a detailed coupling structure of the pillar member and the steel beam member.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention is a "steel frame beam curved at a bending rate so as to correspond to the stress form received by the central portion and both ends of the structural structure beam member; Beam-end concrete 70 coated on both ends of the steel beam 20 to maintain the curved state of the end; And a slab concrete 60, which is built on the upper part of the steel frame beam 20 and maintains the curved state of the central portion. It provides a long-span structure configured to resist the deflection and load of the beam, including.

The steel frame beam 20 is a member for securing a long span of a building, and an H-shaped steel member composed of an upper and lower flanges and a web may be applied.

In the present invention, by making the steel beam 20 to be curved in the opposite direction of the dead load acting on the beam member of the building can be made to correspond to the bending moment largely applied to the center as shown in (a) of [Fig. 1]. Accordingly, even if sagging occurs in the steel beam, the structure that is curved in the upward direction will only behave flatly, so the structural safety of the building will not be impaired. However, even if the cheolgolbo 20 is curved, as the radius of curvature is large and the length is long, as shown in [FIG. 3] to [FIG. 5], identification of the curved state may be difficult with the naked eye. In FIG. 3 to FIG. 5, the curved direction is separately indicated for the conceptual illustration of the steel frame beam.

In addition, since the steel beam made of steel has its own elasticity, there is a need for a means to maintain the curvature of the steel beam against the elastic recovery force.

In the present invention, the beam-end concrete 70 covered at both ends of the steel beam 20 and the slab concrete 60 built on the upper part of the steel beam 20 by the compressive force of the steel beam 20 and the center part Make sure that the curvature is maintained.

The steel beam 20, the center member 21 and the side member 22 is coupled, the side member 22 is formed so that the longitudinal section is larger than the center member 21 (hereinafter referred to as 'side cross-section steel frame beam') Can be applied. Accordingly, one end of the side member 22 is fastened to the end of the center member 21 and the other end is fastened to the pillar member 10. Specifically, each side end portion of the center member 21 and the side member 22 is finished with an end plate, and the end plate is in contact with each other, and the center member 21 and the side member 22 are fastened. The side member 22 and the pillar member 10 may be fastened. Since the cross-section of the steel cross-section is made up of a large cross-section on the end side, it is possible to reduce the self-weight of the steel cross-beam and effectively counteract shear forces, bending moments, and the like.

In addition, the present invention "(a) coupling the steel frame beam (20) between the pillar members (10); (b) placing a hydraulic jack 30 under the steel frame beam 20; (c) pushing up the steel beam 20 with the hydraulic jack 30, and bending the steel beam 20 at a bending rate to correspond to the stress forms received by the center and both ends of the building structure beam member; (d) while maintaining the pressing force of the hydraulic jack 30, the height of the copper bar 20 is installed in the lower part of the steel beam 20, and the copper bar 50 according to the curved shape of the steel beam 20 ) By adjusting the height of the copper bar 50 is installed to maintain the curved shape by supporting the cheolgolbo 20, and recovering the hydraulic jack 30; And (e) covering the beam-end concrete 70 at the end of the steel frame beam 20, constructing the slab concrete 60 at the top, and dismantling the copper bar 50; A method of constructing a long span structure including the same is provided.

Hereinafter, the present invention will be described in detail with each step along with the accompanying drawings.

1.Step (a)

This step is a step of coupling the steel frame beam between the pillar members as shown in [Fig. 2]. The above-mentioned steel cross-section steel cross-beam can be applied.

In addition, by combining the support plate 80 supporting the end of the steel beam 20 from the bottom as shown in [Fig. 6] to the pillar member, in step (a), the side of the pillar member 10 and A process of fastening an end side surface of the steel frame beam 20 (hereinafter, a lateral coupling process) and a process of fastening the bottom surface of the end plate 80 and the steel frame beam 20 (hereinafter, a vertical coupling process) can be performed together. have. The lateral bonding process and the up-and-down bonding process have no particular order.

Conventionally, the coupling of the pillar member 10 and the steel frame beam 20 has been performed only by the lateral coupling process, but the coupling state between the pillar member 10 and the steel frame beam 20 is more stably performed by performing the vertical coupling process together. It can secure and strengthen the resistance to shear force and bending moment.

For bearing reinforcement of the base plate 80 may be reinforced between the lower surface of the side and the base plate of the post member (10) on the inclined member, as shown in [6], the installation structure of the guide plate is tapered cheolgolbo It can also be applied to the combination of the side member and the center member.

2. Step (b)

This step is a step of disposing the hydraulic jack 30 under the steel beam (20).

The hydraulic jack 30 is a tool to force the steel beam 20 to bend upward by the step (d) below, the center of the steel beam 20 to bend the center and end of the steel beam 20, respectively. And a curvature inflection point at both sides (curvature inflection point when the steel beam 20 is bent at a curvature so as to correspond to a stress form received by the center and both ends of the beam member of the building structure). The hydraulic jack 30 can be adjusted differently the amount of force depending on the placement point, as shown in [Fig. 3] can be installed on the base (基 [, 40).

3. Step (c)

This step pushes up the steel beam 20 with the hydraulic jack 30, as shown in [Fig. 3], so that the steel beam 20 corresponds to the stress form received by the center and both ends of the beam member of the building structure, respectively. This is the step of curvature at the curvature.

That is, in this step, the steel beam 20 is bent in the opposite direction of the dead load acting, and corresponds to a bending moment largely applied in the center as shown in (a) of FIG. 1, and later the steel beam Even if sagging occurs in (20), the structural stability of the building is not impaired because the curved upward direction only acts to be flattened.

5. Step (d)

This step, while maintaining the pressing force of the hydraulic jack 30, as shown in [Fig. 4], the height of the copper bar 20 is installed in the lower part of the control bar 50, the steel beam 20 It is a step of adjusting the height of the copper bar 50 according to the curved shape of the copper bar 50 so as to maintain the curved shape by supporting the steel beam 20, and recovering the hydraulic jack 30.

 That is, this step is a process of replacing the curved state of the steel frame beam 20 by the hydraulic jack 30 with the state maintained by the movable bar 50, wherein the movable bar 50 is located between the hydraulic jack placement points. Can be placed.

Since the steel beam 20 is elastic, it is necessary to have a means for maintaining a curved state against elastic recovery force until it is settled integrally with the beam-end concrete 70 and the slab concrete 60, which will be described later. 20) It is to utilize the copper bar, which is necessary for the construction of the slab on the upper part, as a means for maintaining the curved state of the steel frame beam.

6. Step (e)

This step is to cover the beam-end concrete (70) at the end of the steel beam (20), as shown in [Fig. 5], after constructing the slab concrete (60) on the top to disassemble the copper (50) It is a step. The beam-end concrete 70 and the slab concrete 60 can be constructed sequentially or simultaneously.

In the state where the steel beam 20 is integral with the beam-end concrete 70 and the slab concrete 60, the end of the steel beam 20 is curved by the compressive bearing force of the lower beam-end concrete 70. It is fixed in a state, and the central portion of the steel frame beam 20 is fixed in a curved state by the compressive bearing force of the slab concrete 60. The beam-end concrete 70 may adjust the covering length in consideration of the effect of maintaining the curved state of the end of the steel beam 20 and the interference with the copper bar 50 installed in step (e).

The compressive bearing capacity of the beam-end concrete 70 and the slab concrete 60 also acts as a pre-stress for the steel beam 20 to share the dead load applied to the steel beam 20, and the steel beam 20 ).

The present invention has been described in detail above along with specific examples. However, the present invention is not limited by the above embodiments, and can be modified and modified in a range without departing from the gist of the present invention. Therefore, the claims of the present invention include such modifications and variations.

10: Pillar member
20: steel frame beam 21: center member 22: side member
30: hydraulic jack 40: expectations 50: round
60: slab concrete 70: beam-end concrete
80: support plate 85: inclined member

Claims (3)

Steel frame beams curved with a double curvature to correspond to the stress form received by the center and both ends of the building structure beam member;
Beam-end concrete that is coated on both ends of the steel beam to maintain the curved state of the end; And
A slab concrete built on the upper portion of the steel frame beam to maintain a curved state of the central portion; Long span structure configured to resist deflection and load of the beam, including.
In claim 1,
The steel frame beam is a long span structure characterized in that the center member and the side member are combined, and the side member has a larger longitudinal section than the center member.
(A) bonding the steel beam between the pillar members;
(c) disposing a hydraulic jack under the steel frame beam;
(c) pushing up the steel beams with the hydraulic jacks, and bending the steel beams at a bending rate to correspond to the stress forms received by the center and both ends of the beam member of the building structure;
(d) While maintaining the pressing force of the hydraulic jack, a copper bar whose height is adjusted is installed at the lower portion of the steel beam, and the copper bar is curved by supporting the steel beam by adjusting the height of the copper bar according to the curved shape of the steel beam. Installing to maintain the shape, and recovering the hydraulic jack; And
(e) covering the beam-end concrete at the end of the steel frame beam, constructing slab concrete on the upper part, and dismantling the copper bar; Long span structure construction method comprising a.

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