KR102278450B1 - Truss hybrid beam with wide Precast concrete lower flange - Google Patents

Abstract

The present invention consists of an n-type or u-shaped upper-side rigid body in the upper part, and a lower flange made of concrete and a lattice material connecting it to the lower part, so as to effectively resist the compressive force of the upper part and to be intermediate in the longitudinal and transverse directions, respectively. It relates to a truss composite beam having a PC lower flange that enables the deck to be mounted on the upper part of the middle beam while reducing the cross-sectional height by reinforcing the lattice material to constitute the vertical beam and the middle beam.
A preferred embodiment of the present invention is a sanghyeon rigid body having an n-type or u-type cross section; a longitudinal tension member configured to be spaced apart from the lower part of the upper body by a predetermined distance; a lattice material which is repeatedly configured to be inclined so that a certain angle is repeated and coupled to connect the upper body rigid body and the longitudinal tension member; a middle column joined in the longitudinal direction to a certain height of the lattice material; a plurality of intermediate columns configured in the transverse direction to intersect the intermediate columns and 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; a hoop muscle configured to surround the longitudinal tension member and configured at regular intervals in the longitudinal direction of the longitudinal tension member; The longitudinal tension member, the hoop muscle, and the lower flange composed of concrete parallel to the upper surface rigid body so as to be buried to a certain height from the lower end of the lattice material;

Description

Truss hybrid beam with wide Precast concrete lower flange

The present invention relates to a truss composite beam having a PC lower flange, and more particularly, an n-type or u-shaped upper-side rigid body is configured on the upper part, and a lower flange made of concrete and a lattice material connecting it are formed on the lower part. , PC lower flange that allows the deck to be mounted on the upper part of the middle crossbar while effectively resisting the compressive force of the upper part while reducing the cross-sectional height by reinforcing the lattice material by configuring the middle column and the middle column respectively in the longitudinal and lateral directions. It relates to a truss composite beam having

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, and by configuring an n-type or u-shaped rigid body in the upper part and a lower flange made of concrete and a lattice material connecting the same to the lower part, it is effective for the compressive force of the upper part. While resisting, integrity with cast-in-place concrete can be secured without a separate shear connector, and the lattice material can be reinforced to reduce the cross-section height by composing the middle column and the middle column in the longitudinal and lateral directions, respectively. An object of the present invention is to provide a truss composite beam having a PC lower flange that enables the mounting of the deck on the upper part.

The present invention is a rigid body having an n-type or u-type cross-section; a longitudinal tension member configured to be spaced apart from the lower part of the upper body by a predetermined distance; a lattice material that is repeatedly configured to be inclined so that a certain angle is repeated and is coupled to connect the upper string member and the longitudinal tension member at both sides of the upper line rigid body; a middle column joined in the longitudinal direction to a certain height of the lattice material; a plurality of intermediate columns configured in the transverse direction to intersect the intermediate columns and 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; a hoop muscle configured to surround the longitudinal tension member and configured at regular intervals in the longitudinal direction of the longitudinal tension member; To provide a truss composite beam having a PC lower flange, characterized in that it comprises a longitudinal tension member, a hoop muscle, and a lower flange composed of concrete parallel to the upper surface rigid body to be buried to a certain height from the lower end of the lattice material. .

In addition, it is intended to provide a truss composite beam having a PC lower flange, characterized in that the longitudinal tension member is made of a wire of a certain length and is respectively joined to the lower portion of the lattice material.

In addition, the longitudinal tension member is to provide a truss composite beam having a PC lower flange, characterized in that made of a plate shape of a certain size.

In addition, the longitudinal tension member is to provide a truss composite beam having a PC lower flange, characterized in that made to have a u-shaped cross-section.

In addition, the hoop muscle is made of a C-shape with the other side open, a fitting member fitted from one side of the longitudinal tension member to the other side, and a closing member configured to be joined to the fitting member to close the other opened side of the fitting member. To provide a truss composite beam having a PC lower flange, characterized in that made by

In addition, the longitudinal tension member is formed in a plate shape in a certain section from both ends in the longitudinal direction to the inside so that the upper part is joined to the central part in the width direction of the longitudinal tension member or both sides of the upper-side rigid body, and the lower part is embedded in the lower flange to a certain height. To provide a truss composite beam having a PC lower flange, characterized in that the end reinforcement plate is configured.

In addition, the end reinforcing plate is a truss composite having a PC lower flange, characterized in that when a pair of reinforcing plates are spaced apart by a certain distance and the lower end is joined to the longitudinal tension member when the upper portion is respectively joined to both sides of the upper side rigid body We would like to provide

In addition, when the end reinforcing plate is configured in the central portion in the width direction of the longitudinal tension member, a horizontal plate-shaped reinforcing plate is configured at the lower end of the end reinforcing plate, and the truss having a PC lower flange, characterized in that it is embedded in the lower flange We would like to provide a composite report.

In addition, it is intended to provide a truss composite beam having a PC lower flange, characterized in that a plurality of through holes are formed in the end reinforcing plate.

In addition, it is intended to provide a truss composite beam having a PC lower flange, characterized in that the upper rigid body is filled with a filler made of high-strength mortar or concrete therein.

In addition, the lower flange intends to provide a truss composite beam having a PC lower flange, characterized in that a certain section protrudes upward from both ends in the width direction to form a protruding jaw.

In addition, a pair of mounting members consisting of a vertical plate and a horizontal plate extending in the horizontal direction from the upper end of the vertical plate is configured at both sides in the width direction of the lower flange so that the horizontal plate is located inward or outward in the width direction of the lower flange. To provide a truss composite beam having a PC lower flange, characterized in that it is embedded in the lower flange from the lower end to a certain height.

In addition, it is intended to provide a truss composite beam having a PC lower flange, characterized in that the lower end of the vertical plate of the mounting member is joined to the hoop muscle, and the horizontal plate is configured to be joined to the intermediate crossbar.

The truss composite beam having a PC lower flange of the present invention is composed of an n-type or u-type upper-side rigid body at the upper part and a lower flange made of concrete and a lattice material connecting it at the lower part, effectively resisting the compressive force of the upper part. Integrity with cast-in-place concrete can be secured without a separate shear connector, and the cross-section height can be reduced by reinforcing the lattice material by composing the middle column and the middle column in the longitudinal and lateral directions, respectively, and There is a very useful effect that allows the deck to be mounted.

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 composite beam having a PC lower flange of the present invention.
FIG. 2 is a cross-sectional view of FIG. 1 .
3 to 5 are cross-sectional views illustrating another embodiment of FIG. 2 .
6 and 7 are perspective and cross-sectional views of an embodiment in which an end reinforcement plate is applied to the present invention.
Figure 8 is a view showing an embodiment of the use of a truss composite beam having a PC lower flange of the present invention.
9 is a view showing an embodiment in which a protruding jaw portion or a mounting member is configured in a truss composite beam having a PC lower flange 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.

Figure 1 is a perspective view showing a truss composite beam having a PC lower flange of the present invention, Figure 2 is a cross-sectional view of Figure 1 above.

Truss composite beam (1) having a PC lower flange of the present invention is a sanghyeon rigid body (10) having an n-type or u-type cross section; a longitudinal tension member 20 configured to be spaced apart by a predetermined distance from the lower portion of the upper body 10; a lattice material 30 coupled to each side of the upper rigid body 10 to connect the upper rigid body 10 and the longitudinal tension member 20; a middle column 40 joined in the longitudinal direction to a predetermined height of the lattice material 30; A plurality of intermediate columns 50 and configured in the transverse direction to intersect with the intermediate columns 40; The hoop muscle 70 and the longitudinal tension member 20 configured to surround the longitudinal tension member 20, the hoop muscle 70 and the upper rigid body 10 so as to be embedded from the lower end of the lattice material 30 to a certain height. ) and a lower flange 80 composed of concrete in parallel; it is made to effectively resist the compressive force of the upper while making it easy to synthesize, and the middle column 40 and the intermediate cross bar 50 are made of a lattice material (30) By reinforcing the lattice material 30 so that it behaves integrally to reduce the cross-sectional height, the deck is mounted on the upper part of the intermediate crossbar 50 so that the mounting height of the deck can be adjusted. can

The upper rigid body 10 is configured in the longitudinal direction of the truss composite beam 1 having a PC lower flange, thereby increasing the buckling strength against the compressive force of the upper element with respect to the positive moment of the central part generated in the construction stage. , As in FIG. 3b , the rigid upper body 10 may be filled with a filler 19 made of high-strength mortar or concrete therein to reinforce the cross section of the upper surface rigid body 10 .

3 to 5 are cross-sectional views illustrating another embodiment of FIG. 2 .

The upper rigid body 10 is made of steel and consists of a horizontal plate 11 having 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, as shown in FIG. As in, it may be formed to have an n-type cross-section, and also, as in FIG. 3, the side plates 12 are extended upwards from both ends of the horizontal plate 11 in the width direction to be formed to have a u-shaped cross-section. may be

In this way, the upper rigid body 10 is formed to have an n-type or u-shaped cross section so that concrete is simultaneously poured on the cross section of the upper surface rigid body 10 during the construction of the floor plate slab. While it is possible to increase the buckling strength against the compressive force of the upper element against the slab, it can also serve as a shear connector with the slab slab by embedding it in the slab slab.

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.

The longitudinal tension member 20 is configured to be spaced apart from the lower part of the upper-side rigid body 10 by a certain distance, and is configured in parallel with the upper-side rigid body 10 in a plate shape of a certain size as shown in FIG. 3 , and the lattice material 30 ) can be configured such that the lower end is joined, and as shown in FIG. 4, it is made of a wire of a certain length, such as a steel bar, a cheonggeun, a square material, and is joined to the lower end of the lattice material 30, respectively.

In addition, as shown in FIG. 5, the longitudinal tension member 20 is made of a horizontal plate 20a and a side plate 20b extending upward from both sides of the horizontal plate 20a in the width direction to have a u-shaped cross section. In order to increase the rigidity by reinforcing the horizontal plate 20a, it is possible to provide a joint surface to which the truss 30 is joined at the same time.

The lattice material 30 may use a variety of known products that are repeatedly configured to be inclined so that a certain angle is repeated, the lower part is joined to the longitudinal tension member 20 by a known method such as welding, and the upper part is a vertical rigid body (10). ) is joined to the inner or outer surface of the side plate 12 by a variety of known methods such as welding.

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 to protrude outward by a predetermined length may be additionally configured to provide a mounting surface such as a PC slab or deck.

In addition, the intermediate column 40, which is positioned and joined 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 again the intermediate column 50 is also the lattice material 30 ) and the intermediate column 40 so that it can act integrally with the lattice material 30, and as the cross-sectional height increases, the lattice material 30 is reinforced without an increase in the cross-sectional size to prevent compression buckling. can make it

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 may be configured in plurality, may be spaced apart at regular intervals, or may be configured to be densely configured only at the end where the shear force is large.

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.

In the present invention, since the lower flange 80 made of concrete is formed in the lower part of the cross section, it is configured to surround the longitudinal tension member 20 for this purpose, and a hoop muscle 70 is formed at regular intervals in the longitudinal direction of the longitudinal tension member. do.

The hoop muscle 70 may have various shapes, but since the longitudinal tension member 20 may have various shapes such as a wire rod, a plate, and a U-shaped cross-section, installation of the hoop muscle 70 may become difficult. , in order to facilitate installation, the hoop muscle 70 is formed in a C-shape with the other side open, and the fitting member 71 fitted in the other direction from one side of the longitudinal tension member 20, and the opening of the fitting member 71 It may be made of a closing member 72 configured to be joined to the fitting member 71 to close the other side.

That is, the fitting member 71 is installed by pushing it from one side to the other side so that the opening surrounds the longitudinal tension member 20 at a predetermined position in the longitudinal direction of the longitudinal tension member 20, and again the fitting member 71 is The opened other end may be closed by a variety of known methods such as welding or jointing with the closing member 72 .

The closing member 72 is made of a wire of a certain length in the vertical direction, or is made of a L-shape or a C-shape by bending the end to be joined at the other end of the fitting member 71, or a wire of a certain length in the horizontal direction is inserted It may be laminated at the open end of the member 71 to be finished by welding.

In the present invention, a lower flange 80 made of concrete is configured at the lower portion of the cross-section, and the longitudinal tension member 20, the hoop muscle 70 and the lattice material 30 are formed inside the cross-section of the lower flange 80. It is configured to be buried up to a certain height in the

Although not shown, prestress may be introduced into the lower flange 80 located at the lower portion of the cross-section, and as the prestress is introduced, rigidity and strength are improved, thereby reducing the floor height, and in particular, the lower portion of a relatively small area compared to the general PC member. Since the prestress is introduced only to the flange 80, a high compressive stress is introduced to the tensile-side concrete compared to the conventional PC member, so there is an advantage that the flexural cracking strength is very high after synthesis with the cast-in-place concrete. Therefore, it is possible to maximize the deflection control under the working load, and since the deck plate is mounted on the upper surface of the lower flange 80, it is easy to reduce the floor height, so it is very suitable for a long span structure.

6 and 7 are a perspective view and a cross-sectional view of an embodiment in which an end reinforcing plate is applied to the present invention.

6 and 7, a plate-shaped end reinforcing plate 60 may be configured in a predetermined section from both ends in the longitudinal direction of the longitudinal tension member 20 to the inside.

The end reinforcing plate 60 is formed in a plate shape in a certain section from both ends in the longitudinal direction of the longitudinal tension member 20 to the inside, so that the upper portion is the central part in the width direction of the longitudinal tension member 20 or both sides of the upper side rigid body 10 . Each is joined to the lower end is configured to be embedded in the lower flange (80) up to a certain height.

The end reinforcing plate 60 is, as shown in FIGS. 6a and 6b, when the longitudinal tension member 20 has a plate shape or a U-shaped cross-section of a certain size, the central portion of the longitudinal tension member 20 and the upper face It is possible to connect the lower surface of the rigid body 10, and as shown in FIGS. 7A and 7B, a pair is spaced apart by a certain distance so that the upper part is joined to both sides of the upper part of the rigid body 10, and the lower part is a longitudinal tension member. (20) so as to be joined to the shear of the end can be reinforced.

In addition, as in FIG. 6c , when the longitudinal tension member 20 is made of a wire of a certain length and the end reinforcing plate 60 is configured in the central portion of the longitudinal tension member 20 in the width direction, the end reinforcing plate 60 ) at the lower end of the horizontal plate-shaped reinforcing plate 62 is configured, so as to be embedded in the lower flange 80 to serve to reinforce the end reinforcing plate 60 .

In the case of the end reinforcing plate 60 as described above, the upper end is joined to the upper rigid body 10 , and in the case of the lower end, it can be configured to be joined to the longitudinal tension member 20 , and more than the longitudinal tension member 20 . It may be configured without being joined to the longitudinal tension member 20 at an upwardly spaced position.

As such, a horizontal plate-shaped reinforcing plate 62 may be configured at the lower end of the end reinforcing plate 60 when the lower end is not joined to the longitudinal tensile member 20 in the longitudinal direction. Not only when it is configured in the central portion of the tension member 20 in the width direction, but also when the end reinforcing plate 60 is respectively joined to both sides of the upper rigid body 10, although not shown, a horizontal plate-shaped reinforcing plate 62 at the lower end ) can be configured.

In particular, a plurality of through holes 61 may be formed in the end reinforcing plate 60 to allow concrete to flow during concrete pouring.

Figure 8 is a view showing an embodiment of the use of a truss composite beam having a PC lower flange of the present invention.

Truss composite beam 1 having a PC lower flange of the present invention may reduce the amount of concrete pouring by mounting the end of the PC slab or deck 7 to the height of the upper part of the intermediate crossbar 50, at this time, Between the upper surface of the lower flange 80 and the lower surface of the PC slab or deck 7, a separate formwork may be installed and concrete may be poured.

9 is a view showing an embodiment in which a protruding jaw portion or a mounting member is configured in a truss composite beam having a PC lower flange of the present invention.

In addition, as in FIG. 9a, the lower flange 80 protrudes upward in a certain section from both ends in the width direction to form the protruding jaw 81, so that the PC slab or deck 7 can be easily mounted. , by blocking the space between the upper surface of the lower flange 80 and the lower surface of the PC slab or deck 7, it is possible to facilitate the pouring of concrete on the upper part of the lower flange 80.

In particular, as in FIGS. 9b and 9c with the same function, the mounting member 82 consisting of a vertical plate 821 and a horizontal plate 822 extending in the horizontal direction from the upper end of the vertical plate 821 is a lower flange 80 ), a pair is configured symmetrically or asymmetrically on both sides in the width direction and is embedded in the lower flange 80 to a certain height from the lower end of the vertical plate 821, and although not shown, the buried part has a known technique. It can also be used to arrange shear connectors and the like.

At this time, the horizontal plate 822 may be directed inward in the width direction of the lower flange 80 as in FIG. 9b or may be positioned outward in the width direction of the lower flange 80 as in FIG. 9c .

In addition, the lower end of the vertical plate 821 of the mounting member 82 is joined to the hoop muscle 70 , and the horizontal plate 822 is configured to be joined to the intermediate crossbar 50 so that it can behave integrally.

The truss composite beam having a PC lower flange of the present invention as described above is composed of an n-type or u-shaped upper-side rigid body at the upper portion, and a lower flange made of concrete and a lattice material connecting the same at the lower portion, so that the compression force of the upper part is reduced. While effectively resisting, it is possible to secure the integrity with cast-in-place concrete without a separate shear connector, and by configuring the middle column and middle column in the longitudinal and lateral directions, respectively, the lattice material can be reinforced to reduce the cross-sectional height while reducing the cross-sectional height. There is a very useful effect to enable the mounting of the deck on top of the.

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 composite beam with PC lower flange
10: upright rigid body
11: horizontal plate
12: vertical plate
20: longitudinal tension member
30: lattice material
40: middle column
50: middle crossbar
60: end reinforcement plate
61: through hole
70: hoop muscle
80: lower flange

Claims (13)

An n-type or a u-shaped rigid body 10 having a cross section and;
a longitudinal tension member 20 configured to be spaced apart by a predetermined distance from the lower portion of the upper body 10;
A lattice material 30 that is repeatedly configured to be inclined to repeat a certain angle and is coupled to connect the upper rigid body 10 and the longitudinal tension member 20 on both sides of the upper rigid body 10, respectively, and
a middle column 40 joined in the longitudinal direction to a predetermined height of the lattice material 30;
A plurality of intermediate crossbars 50 that are configured in the transverse direction to intersect the middle column 40 and are joined to the lattice material 30 and the intermediate column 40 so that both ends protrude a predetermined length to the outside of the lattice material 30 on both sides. )Wow;
a hoop muscle 70 configured to surround the longitudinal tension member 20 and configured at regular intervals in the longitudinal direction of the longitudinal tension member;
The longitudinal tension member 20, the hoop muscle 70, and the lower flange 80 composed of concrete in parallel with the upper surface rigid body 10 so as to be buried from the lower end of the lattice material 30 to a certain height; and ,
In a predetermined section from both ends in the longitudinal direction of the longitudinal tension member 20 to the inside, the upper part is joined to the central part in the width direction of the longitudinal tension member 20 or both sides of the upper side rigid body 10, and the lower part is constant. The end reinforcing plate 60 is configured to be embedded in the lower flange 80 up to the height,
When the end reinforcing plate 60 is configured in the width direction central portion of the longitudinal tension member 20, a horizontal plate-shaped reinforcing plate 62 is configured at the lower end of the end reinforcing plate 60, and is embedded in the lower flange 80. Truss composite beam having a PC lower flange, characterized in that it is configured. The method according to claim 1,
The longitudinal tension member 20 is a truss composite beam with a PC lower flange, characterized in that it is made of a wire of a certain length and is respectively joined to the lower portion of the lattice member 30. The method according to claim 1,
The longitudinal tension member 20 is a truss composite beam having a PC lower flange, characterized in that it has a plate shape of a certain size. The method according to claim 1,
The longitudinal tension member 20 is a truss composite beam having a PC lower flange, characterized in that it is made to have a u-shaped cross section. The method according to claim 1,
The hoop muscle 70 is formed in a C-shape with the other side open, and the fitting member 71 fitted in the other direction from one side of the longitudinal tension member 20 and the other open side of the fitting member 71 are fitted to close them. Truss composite beam having a PC lower flange, characterized in that it comprises a finishing member 72 configured by being joined to the member 71. delete delete delete The method according to claim 1,
Truss composite beam having a PC lower flange, characterized in that a plurality of through-holes (61) are formed in the end reinforcing plate (60). The method according to claim 1,
A truss composite beam having a PC lower flange, characterized in that the upper rigid body 10 is filled with a filler 19 made of high-strength mortar or concrete therein. The method according to claim 1,
The lower flange 80 is a truss composite beam having a PC lower flange, characterized in that a certain section protrudes upward from both ends in the width direction to form a protruding jaw portion 81 . The method according to claim 1,
The mounting member 82 consisting of a vertical plate 821 and a horizontal plate 822 extending in the horizontal direction from the upper end of the vertical plate 821 has the horizontal plate 822 inward or outward in the width direction of the lower flange 80 . A truss composite beam having a PC lower flange, characterized in that a pair is formed on both sides of the lower flange 80 in the width direction to be positioned and is embedded in the lower flange 80 from the lower end of the vertical plate 821 to a certain height. 13. The method of claim 12,
The lower end of the vertical plate 821 of the mounting member 82 is joined to the hoop muscle 70, and the horizontal plate 822 is a truss composite having a PC lower flange, characterized in that it is configured to be joined to the intermediate crossbar (50). see.

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