KR102278451B1 - Truss Slim Girder Using longitudinal and lateral member - Google Patents

Abstract

The present invention relates to a truss slim beam using an intermediate column and an intermediate crossbar, and more particularly, an n-type upper-side rigid body in the upper part and a lower flange and a middle crossbar made of a lattice material connecting them in the lower part Using the used truss slim beam, it effectively resists the compressive force of the upper part and makes it easy to synthesize. It relates to a truss slim beam using an intermediate column and an intermediate cross column that enables the deck to be mounted on the deck.
A preferred embodiment of the present invention includes a rigid body having an n-type cross-section; A plate-shaped longitudinal tension plate configured to be spaced apart by a predetermined distance from the lower portion of the upper body; a lattice material that is repeatedly configured to be inclined to repeat a certain angle and is coupled to connect the vertical tension plate with the upper body; a middle column joined in the longitudinal direction to a certain height of the lattice material; It is configured in the transverse direction to intersect the middle column, and a plurality of intermediate columns joined to the lattice material and the intermediate column so that both ends protrude a predetermined length to the outside of the lattice material on both sides.

Description

Truss Slim Girder Using longitudinal and lateral member

The present invention relates to a truss slim beam using an intermediate column and an intermediate crossbar, and more particularly, an n-type upper-side rigid body in the upper part and a lower flange and a middle crossbar made of a lattice material connecting them in the lower part. Using the used truss slim beam, it effectively resists the compressive force of the upper part while making it easy to synthesize, and the lattice material is reinforced without increasing the size by composing the middle column and the middle column in the longitudinal and lateral directions, so that the cross-sectional height of the slim beam can be freely It is possible to increase the buckling strength of the lattice material while improving the buckling strength of the lattice material, and by enabling the mounting of floor members made of PC slabs, steel deck hollow slabs, etc. on the upper or lower part of the middle crossbar, the dance can respond to various floor thicknesses regardless of size. It is related to the truss slim beam using the middle column and the intermediate column.

A beam is a structural member that supports a load by bending and shearing, and is also called a flexural member because the bending moment mainly dominates the structural behavior. Stress and deformation due to bending and shearing of the beam occur mainly, but if the applied load does not coincide with the shear center of the section, torsion may be accompanied. Therefore, the beam must have sufficient bending strength and shear strength (or torsional strength), and since it is used as a horizontal member, usability against deflection must be secured.

In particular, as the cross-section of the steel beam member, the H-shaped cross-section is mainly used, and the box-type, I-type, and C-shaped cross-sections are also used, and a slim built-up beam manufactured by joining is sometimes used, and twisted. A box section is sometimes used when receiving a load or when the buckling length is very long. In particular, the height (thickness) of the base plate and the height of the steel beam member are different because it is common for steel beam members to support the base plate on the cross section of the upper element. It is difficult to reduce the height of the floor as it has an exposed structure that must be secured.

And, in order to increase the buckling strength against the compressive force of the upper element in response to the positive moment of the central part generated during the construction stage, the existing beam member had problems in that the cross section was enlarged or the amount of steel used was increased, and in the case of a long span, There was a problem in that the torsional resistance performance was deteriorated because the compressive section of the upper element was small for horizontal and asymmetric loads as well as vertical loads during construction.

As the technology that is the background of the present invention, there is Korean Patent Registration No. 0626542 "Composite beam structure using steel plate forming beam and concrete" (Patent Document 1). In the background art, '(a) a bottom plate formed by horizontally installing a thin plate-type steel plate to form the lower surface of the beam; a pair of side vertical plates extending in a vertical direction from both ends of the bottom plate and forming both sides of the beam; a support wing portion extending horizontally from the upper end of the side vertical plate; a central vertical plate standing in a vertical direction from the upper center of the bottom plate and formed to have a longer length than the length of the side vertical plate; a steel plate forming beam comprising; an upper flange extending horizontally from the upper end of the central vertical plate to form a 'T' shape with the central vertical plate; (b) a bottom plate unit installed so that the end is supported on the upper portion of the supporting wing of the steel plate forming beam to form a slab structure; and (c) beam-slab concrete poured integrally into the inside of the steel plate forming beam and the upper part of the floor plate unit; One end of the bottom plate is bent upward to form a side vertical plate, and the upper end of the side vertical plate is horizontally bent to form a support wing, and at the same time, the other side of the bottom plate is bent upward to form a central vertical plate, and the center A half-steel plate-formed beam is prepared by horizontally bending the upper end of a vertical plate to form an upper flange, and a pair of half-steel plate-formed beams are attached to each other so that the central vertical plates face each other. Using a steel plate forming beam and concrete A composite beam structure is proposed.

However, the background art also had a problem in that the cross section was enlarged or the amount of steel used was increased in order to increase the buckling strength against the compressive force of the upper element in response to the positive moment of the central part generated in the construction stage.

Republic of Korea Patent Registration No. 0626542 "Composite beam structure using steel plate forming beam and concrete"

The present invention is to solve the above problems, using a truss slim beam using an intermediate column and an intermediate crossbar made of a lower flange and a lattice material connecting the lower flange and the lower flange to the upper part of the upper part of the n-type rigid body. It effectively resists compressive force while making it easy to synthesize, and the lattice material is reinforced without increasing the size by configuring the middle column and the middle column in the longitudinal and lateral directions, respectively, so that the cross-sectional height of the slim beam can be freely increased and the buckling strength of the lattice material The use of intermediate columns and intermediate columns that can respond to various floor thicknesses regardless of size by making it possible to mount floor members made of PC slabs, steel deck hollow slabs, etc. on the upper or lower part of the intermediate column The purpose is to provide a truss slim beam.

The present invention is a sanghyun rigid body having an n-type cross section; A plate-shaped longitudinal tension plate configured to be spaced apart by a predetermined distance from the lower portion of the upper body; A lattice material that is repeatedly configured to be inclined so that a certain angle is repeated and a pair is coupled to connect the upper-side rigid body and the longitudinal tension plate; a middle column joined in the longitudinal direction to a certain height of the lattice material; A truss slim using an intermediate column and an intermediate column, characterized in that it comprises; a plurality of intermediate columns that are configured in the transverse direction to intersect the intermediate column and are joined to the intermediate column so that both ends protrude a predetermined length to the outside of the lattice material on both sides. We would like to provide

In addition, it is intended to provide a truss slim beam using an intermediate column and an intermediate cross column, characterized in that the horizontal plate of the vertical rigid body is formed through a plurality of through holes.

In addition, the side form member consisting of a side plate and a mounting plate extending in the horizontal direction from the upper end of the side plate, the middle column and the middle, characterized in that the lower part of the side plate is joined to both ends of the longitudinal tension plate in the width direction, respectively. We would like to provide a truss slim beam using a cross bar.

In addition, the mounting plate is intended to provide a truss slim beam using the middle column and the middle crossbar, characterized in that it is configured to be joined to the upper or lower portion of the intermediate crossbar.

In addition, it is intended to provide a truss slim beam using an intermediate column and an intermediate cross column, characterized in that the side formwork members respectively configured at both ends in the width direction of the longitudinal tension plate are symmetrical.

In addition, it is intended to provide a truss slim beam using an intermediate column and an intermediate cross column, characterized in that the side formwork members respectively configured at both ends in the width direction of the longitudinal tension plate are asymmetrically configured.

In addition, the side formwork members respectively configured at both ends in the width direction of the longitudinal tension plate are truss slim using an intermediate column and an intermediate cross, characterized in that the mounting plate is configured so as to constitute the inner or outer direction of the longitudinal tension plate, respectively. We would like to provide

In addition, in a certain section inward from both ends in the longitudinal direction of the longitudinal tension plate, an end vertical reinforcing plate is configured to connect the central part in the width direction of the longitudinal tension plate and the lower surface of the upper side rigid body. We would like to provide a truss slim beam using

In addition, it is intended to provide a truss slim beam using an intermediate column and an intermediate cross column, characterized in that a plurality of through holes are formed in the end vertical reinforcing plate.

In addition, the middle crossbar is to provide a truss slim beam using the intermediate column and the intermediate crossbar, characterized in that it is configured to be joined to the lattice material and the intermediate column at the same time.

The truss slim beam using the middle column and the middle crossbar of the present invention is composed of an n-type vertical rigid body in the upper part, and the lower flange and the truss slim beam using the middle crossbar made of the lattice material connecting it to the lower part of the upper part using the truss slim beam. It effectively resists compressive force while making it easy to synthesize, and the lattice material is reinforced without increasing the size by configuring the middle column and the middle column in the longitudinal and lateral directions, respectively, so that the cross-sectional height of the slim beam can be freely increased and the buckling strength of the lattice material It has a very useful effect that it can cope with various floor thicknesses regardless of the size of the dance, by enabling the mounting of floor members made of PC slabs, steel deck hollow slabs, etc. on the upper or lower part of the middle crossbar.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a perspective view showing a truss slim beam using the middle column and the middle cross bar of the present invention.
FIG. 2 is a cross-sectional view of FIG. 1 .
3 and 4 are cross-sectional views showing an embodiment in which the side formwork member is configured in the present invention.
5 is a perspective view showing another embodiment of the present invention.
6 is a cross-sectional view of FIG. 5 .
Figure 7 is a view showing an embodiment of the use of a truss slim beam using the middle column and the middle crossbar of the present invention.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

Hereinafter, the technical configuration of the present invention will be described in detail according to a preferred embodiment.

1 is a perspective view showing a truss slim beam using an intermediate column and an intermediate crossbar of the present invention, and FIG. 2 is a cross-sectional view of FIG. 1 .

The truss slim beam (1) using the middle column and the middle cross section of the present invention is a sanghyeon rigid body 10 having an n-type cross section; A plate-shaped longitudinal tension plate 20 configured to be spaced apart from the lower part of the upper rigid body 10 by a predetermined distance; And the lattice material 30 coupled to connect the vertical tension plate 20 with the upper rigid body 10; a middle column 40 joined in the longitudinal direction to a predetermined height of the lattice material 30; It is configured in the transverse direction so as to intersect the middle column 40, and a plurality of intermediate cross bars 50 are joined to the intermediate column 40 so that both ends protrude a predetermined length to the outside of the lattice material 30 on both sides. , to effectively resist the compressive force of the upper part and to facilitate the synthesis, and to configure the middle column 40 and the middle cross bar 50 at a certain height of the lattice material 30 to reinforce the lattice material 30 without increasing the size to make it slim While it is possible to freely increase the cross-sectional height of the beam, it is possible to improve the buckling strength of the lattice material 30 .

In particular, by making it possible to mount the deck on the upper or lower part of the intermediate crossbar 50, it is possible to respond to various floor construction methods (PC slab, steel deck, hollow slab, etc.).

The upper rigid body 10 is configured in the longitudinal direction of the truss slim beam 1 using the middle column and the middle crossbar, so that the compression and flexural buckling strength against the compressive force of the upper element against the static moment of the central part generated in the construction stage can increase

An n-type rigid body 10 is formed of steel and consists of a horizontal plate 11 of a plate shape of a certain length formed horizontally, and a side plate 12 extending downward from both ends in the width direction of the horizontal plate 11 . It may be formed to have a cross-section.

In this way, the uppermost rigid body 10 is formed to have an n-type cross-section, and concrete is simultaneously poured on the cross-section of the upper-hanging rigid body 10 during the construction of the floor plate slab, so that the upper element for the positive moment of the central part generated in the construction stage. It can increase the buckling strength against the compressive force of the slab, and it can also serve as a shear composite connector with the slab slab by being buried to cross reinforcement with the reinforcing bar of the slab deck.

The horizontal plate 11 of the upright rigid body 10 is made in the shape of a horizontal plate of a certain length, and the side plate 12 extending downward from both ends in the width direction of the horizontal plate 11 is the horizontal plate 11 . It serves to increase the rigidity by reinforcing and at the same time provide a joint surface to which the truss 30 is joined.

Since the horizontal plate 11 is embedded in the concrete, it is possible to form a plurality of through-holes 111 or arrange a variety of known shear connectors, and the side plate 12 is made to have a right angle or an inclination angle of the lattice material 30 . Corresponding to the arrangement (right angle, inverted trapezoid, trapezoid), it is possible to increase the contact surface for welding joints.

The longitudinal tension plate 20 is formed in a plate shape of a certain thickness, and is spaced a predetermined distance from the lower portion of the upper surface rigid body 10 to be parallel to the upper surface rigid body 10 .

The above-mentioned rigid body 10 and the longitudinal tension plate 20 are coupled to each other by a lattice material 30 to be interconnected.

As the lattice material 30, various known products that are repeatedly configured to be inclined to repeat a certain angle can be used, and the lower part is joined to the upper surface of the longitudinal tension plate 20 by a known method such as welding, and the upper part is a sanghyeon steel. It is joined to the inner or outer surface of the side plate 12 of the adult 10 by various known methods such as welding.

Such a lattice material 30 can be configured such that, as shown, the upper portion is bonded to the inner surface or the outer surface of the side plate 12 on both sides in the width direction of the upper body 10, respectively, and not shown However, the lattice material 30 may be configured such that a pair is joined to the lower surface of the horizontal plate 11 of the upper staggered rigid body 10 .

Such a longitudinal tension plate 20 may provide a mounting surface of a floor member made of a PC slab, a steel deck hollow slab, or the like.

In particular, in the present invention, the middle column 40 is joined to a certain height of the lattice material 30 in the longitudinal direction, and it is configured in the transverse direction to intersect the intermediate column 40 and both ends of the lattice material 30 on both sides. A plurality of intermediate crossbars 50 joined to the lattice material 30 and the intermediate column 40 are additionally configured to protrude outward by a certain length, so that the mounting surface of the floor member, such as a PC slab, a steel deck hollow slab, etc. can be provided.

In addition, the intermediate column 40 positioned along the inside or the outer side in the longitudinal direction at a certain height of the lattice material 30 is joined to the lattice material 30 by a method such as welding, and the intermediate column 50 is It can be joined to the middle column 40, and in particular, the middle cross bar 50 can be simultaneously bonded to the lattice material 30 and the intermediate column 40 so that it can behave integrally with the lattice material 30. have. With this configuration, the height of the slim beam can be freely adjusted to improve the buckling strength without increasing the size of the lattice material 30 to prevent lateral buckling.

The middle column 40 may be located outside or inside the lattice material 30 , and one or more may be configured in one lattice 30 .

In addition, the intermediate crossbar 50 is spaced apart in the longitudinal direction of the intermediate column 40, and may be configured in plurality, may be spaced apart at regular intervals, and is buried in concrete and densely configured only at the end where the horizontal shear force is greatly applied. you can make it do

The intermediate column 40 and the intermediate cross bar 50 may be made of various wire rods, such as reinforcing bars, square bars, round bars, and pipes.

3 and 4 are cross-sectional views showing an embodiment in which the side formwork member is configured in the present invention.

3 and 4, the longitudinal tension plate 20 is configured such that separate side formwork members 21 are configured on both sides in the width direction so as not to install a separate formwork plate when pouring concrete while serving as a formwork. , a PC slab, a steel deck hollow slab, and the like may be provided with a mounting surface for the floor member.

The side formwork member 21 is composed of a side plate 212 and a mounting plate 213 extending inward or outward in the width direction from the upper end of the side plate 212, and the side formwork member 21 is a longitudinal tension plate ( 20) is configured by joining the lower portions of the side plates 212 to both ends in the width direction.

The side plate 212 serves as a formwork, and the mounting plate 213 provides a mounting surface for a floor member made of a PC slab, a steel deck hollow slab, or the like.

At this time, the side formwork member 21 is formed to a predetermined thickness thinner than the thickness of the longitudinal tension plate 20, thereby facilitating molding and enhancing economic feasibility while providing a formwork and a mounting surface.

As shown in FIG. 3, when the mounting plate 213 extends outward in the width direction from the upper end of the side plate 212, the side formwork member 21 is formed at both ends of the longitudinal tension plate 20 in the width direction of the side plate ( 212) is joined, and the intermediate crossbar 50 is joined to the upper part of the mounting plate 213 so that it behaves integrally, and a PC slab, a steel deck hollow slab, etc. are used on the upper or lower part of the intermediate crossbar 50. By enabling the mounting of the bottom member 70 made, the dance can respond to various thicknesses of the floor regardless of the size.

In addition, as in FIG. 4 , when the mounting plate 213 extends inward in the width direction from the upper end of the side plate 212 , the side formwork members 21 are side surfaces at both ends of the longitudinal tension plate 20 in the width direction. The lower portion of the plate 212 is joined, and the lower surface or the upper surface of the mounting plate 213 is configured to be joined to the intermediate crossbar 50 so that it behaves integrally.

It is preferable to use the side plate 212 and the mounting plate 213 of the side formwork member 21 symmetrically, but when the bottom member 70 is different, as in FIG. 3b , it is used asymmetrically. You may.

5 is a perspective view illustrating another embodiment of the present invention, and FIG. 6 is a cross-sectional view of FIG. 5 .

5, in a certain section inward from both ends in the longitudinal direction of the longitudinal tension plate 20, the end vertical to connect the central part in the width direction of the longitudinal tension plate 20 and the lower surface of the upper body 10 The reinforcing plate 60 may be configured to reinforce a large shear that occurs during construction of the end portion.

In addition, a plurality of through-holes 61 may be formed in the end vertical reinforcing plate 60 so that the concrete can flow when the concrete is poured.

Figure 7 is a view showing an embodiment of the use of a truss slim beam using the middle column and the middle crossbar of the present invention.

Truss slim beam (1) using the middle column and middle crossbar of the present invention is the end of the floor member 70 made of a PC slab, a steel deck hollow slab, etc., as in FIG. 7a, the height of the longitudinal tension plate 20 It can also be mounted on, and as shown in FIG. 7b, it is also possible to reduce the amount of concrete pouring by mounting at the height of the upper part of the intermediate crossbar 50.

The truss slim beam using the middle column and middle crossbar of the present invention as described above consists of an n-type upper-side rigid body in the upper part, and the lower flange and the lattice material connecting the middle column and the middle crossbar are used in the lower part of the truss slim beam. Thus, it effectively resists the compressive force of the upper part and makes it easy to synthesize, and the lattice material is reinforced without increasing the size by configuring the middle column and the middle column in the longitudinal and lateral directions, respectively, so that the cross-sectional height of the slim beam can be freely increased while the lattice It improves the buckling strength of the material and enables the mounting of floor members made of PC slabs and steel deck hollow slabs on the upper or lower part of the middle crossbar, so that the dance can respond to various floor thicknesses regardless of size. have.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

1: Truss slim beam using middle column and middle crossbar
10: upright rigid body
11: horizontal plate
12: vertical plate
20: longitudinal tension plate
21: side formwork member
30: lattice material
40: middle column
50: middle crossbar
60: end vertical reinforcement plate
61: through hole

Claims (10)

a horizontal plate 11 having a plate shape of a certain length, and a vertical rigid body 10 having an n-type cross section consisting of side plates 12 extending downward from both ends of the horizontal plate 11 in the width direction;
A plate-shaped longitudinal tension plate 20 configured to be spaced apart by a predetermined distance from the lower portion of the upper rigid body 10;
A lattice material 30 which is configured to be repeatedly inclined so that a certain angle is repeated to connect the upper surface rigid body 10 and the longitudinal tension plate 20;
a middle column 40 joined in the longitudinal direction to a predetermined height of the lattice material 30;
It is configured in the transverse direction so as to intersect the middle column 40, and a plurality of intermediate cross bars 50 are joined to the intermediate column 40 so that both ends protrude a predetermined length to the outside of the lattice material 30 on both sides.
The middle crossbar 50 is a truss slim beam using the middle column and the intermediate crossbar, characterized in that it is configured to be joined to the lattice material 30 and the intermediate column 40 at the same time. The method according to claim 1,
The horizontal plate 11 of the sanghyeon rigid body 10 is a truss slim beam using an intermediate column and intermediate crossbar, characterized in that a plurality of through-holes 111 are formed therethrough. The method according to claim 1,
A side formwork member 21 comprising a side plate 212 and a mounting plate 213 extending in the horizontal direction from the upper end of the side plate 212,
Truss slim beam using an intermediate column and intermediate crossbar, characterized in that the lower portions of the side plates 212 are respectively joined to both ends of the longitudinal tension plate 20 in the width direction. 4. The method according to claim 3,
Mounting plate 213 is a truss slim beam using an intermediate column and intermediate crossbar, characterized in that configured to be joined to the upper or lower portion of the intermediate crossbar (50). 3. The method according to claim 2,
A truss slim beam using an intermediate column and an intermediate cross, characterized in that the side formwork members 21 respectively configured at both ends of the longitudinal tension plate 20 in the width direction are symmetrical. 3. The method according to claim 2,
A truss slim beam using an intermediate column and intermediate crossbar, characterized in that the side formwork members 21 configured at both ends in the width direction of the longitudinal tension plate 20 are asymmetrical. 5. The method according to claim 4,
The side formwork members 21 respectively configured at both ends of the longitudinal tension plate 20 in the width direction are intermediate columns, characterized in that the mounting plate 213 is configured in the inner or outer direction of the longitudinal tension plate 20, respectively. and truss slim beam using middle crossbar. The method according to claim 1,
In a certain section inward from both ends in the longitudinal direction of the longitudinal tension plate 20,
Truss slim beam using an intermediate column and intermediate crossbar, characterized in that the end vertical reinforcing plate 60 is configured to connect the central portion of the longitudinal tension plate 20 in the width direction and the lower surface of the upper body 10. The method according to claim 1,
A truss slim beam using an intermediate column and an intermediate crossbar, characterized in that a plurality of through-holes (61) are formed in the end vertical reinforcing plate (60). delete

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