JPH08284308A - Girder having steel-structured middle part and reinforced concrete-structured end part - Google Patents

Abstract

PURPOSE: To make stress smoothly transmitted from a steel girder to precast reinforced concrete parts in a girder for which the middle part is constructed of a structural steel while both ends are constructed of reinforced concrete, and to make joining executable simply at joints between the ends of the steel girder and the precast reinforced concrete parts. CONSTITUTION: In a girder 1 for which the middle part is constructed of structural steel while the ends are constructed of reinforced concrete, precast reinforced concrete parts 3 are formed at both ends of a steel girder 2. Tips of main reinforcements 4 are projected from the precast reinforced concrete parts 3, and the main reinforcements 4 are partly welded to flanges 6 of the steel girder.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a beam having a reinforced concrete end and a steel frame center.

[0002]

2. Description of the Related Art In a building made of reinforced concrete having a large span, a beam 20 having a reinforced concrete structure at its end and a steel frame structure at its center is used as shown in FIG.

It was thought that the beam 20 is constructed by embedding an end portion of a steel frame 40 in a reinforced concrete portion 30 and transmits stress by a bearing mechanism as shown in FIG.

[0004]

However, in the beam having such a structure, the end of the steel frame is embedded in the reinforced concrete portion to increase the strength, but stress concentrates on the portions a and b in FIG. Therefore, the stress was not transmitted smoothly from the steel beam to the reinforced concrete part.

For this reason, conventionally, the cost is increased by shear-reinforcing the portion where the stress is concentrated.

Further, the joining of the end portion of the steel beam and the reinforced concrete portion has been troublesome since it is performed on site.

The present invention has been made in view of the above problems, and an object thereof is to smoothly transmit stress from a steel beam to a reinforced concrete part in a beam having a reinforced concrete structure at the ends and a steel structure at the center. In addition to the above, it is to easily join the end portion of the steel beam and the reinforced concrete portion.

[0008]

According to the invention of claim 1, the precast reinforced concrete parts, in which the tips of the main bars are projected, are formed at both ends of the steel beam, and the precast The main bar embedded in the reinforced concrete part is restrained by a steel plate, and a part of it is welded to the flange of the steel beam, and a support plate is provided on the steel beam at the back end side of the precast reinforced concrete part. According to the invention of claim 2, the precast reinforced concrete portions in which the tips of the main bars are projected are formed at both ends of the steel beam, and the main bars embedded in the precast reinforced concrete sections are restrained by steel plates. In addition, a part of it is welded to the flange of the steel beam, and the main bars on both sides that are not welded to the flange are connected to each other at the top and bottom to form a hoop shape. However, in the invention of claim 1 or 2, the precast reinforced concrete part is provided with a bearing plate on the steel beam at the rear end side of the precast reinforced concrete part. The entire length of the embedded main bar is constrained by a steel plate, and further, in the invention according to claim 1 or 2, a cotter is provided on the tip side of the precast reinforced concrete part. It is to be configured.

[0009]

[Operation] By forming the precast reinforced concrete part with the tip of the main bar protruding at both ends of the steel beam,
The bending moment acting on the steel beam end is smoothly transmitted to the precast reinforced concrete section on the tension side. Further, the bending moment is smoothly transmitted to the precast reinforced concrete portion on the compression side by providing the pressure bearing plate on the steel beam on the mouth end side of the rear end side of the precast reinforced concrete portion. Also,
This transmission is further effectively performed because the main bar is restrained by the steel beam with the steel plate.

A main bar embedded in a precast reinforced concrete part is restrained by a steel plate, and a part of this main bar is welded to a flange of a steel frame beam, and main bars on both sides which are not welded to the flange are respectively connected up and down to form a hoop shape. As a result, the bending moment acting on the steel beam end portion is smoothly transmitted to the precast reinforced concrete portion on the tension side. Further, since the pressure bearing plate is provided on the steel beam at the mouth end surface of the precast reinforced concrete portion on the rear end side, the bending moment is smoothly transmitted to the precast reinforced concrete portion on the compression side.
Further, this transmission is further effectively performed because the main bar is restrained by the steel beam with the steel plate.

Further, since the precast reinforced concrete portions are formed at both ends of the steel beam, joining with the reinforced concrete column can be easily performed.

Further, by forming the precast reinforced concrete portions in which the tips of the main bars are projected at both ends of the steel beam, the steel beams can be embedded up to the reinforced concrete columns, so that the force can be dispersed and transmitted.

Further, the strength of the precast reinforced concrete portion is increased by restraining the entire length of the main reinforcement embedded in the precast reinforced concrete portion with a steel plate.

Further, by providing the cotter on the tip side of the precast reinforced concrete portion, the shear resistance with the reinforced concrete column can be strengthened.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A beam (hereinafter referred to as a beam) having a reinforced concrete structure at its end and a steel frame at its center in the present invention will be described in detail below with reference to the drawings.

1 to 4 show an embodiment of the invention of claim 1, FIG. 1 is a vertical sectional side view of a beam, FIG. 2 is a vertical sectional side view of an end of a beam, and FIG. Plan view, FIG. 4 is A of FIG.
FIG.

As shown in FIG. 1, the beam 1 is constructed by forming precast reinforced concrete parts 3 on both ends of a steel frame beam 2. At this time, the steel frame may be wound with concrete, or may be coated with fireproof instead of winding the concrete.

From the precast reinforced concrete portion 3, a tip portion of a main bar 4 is projected, and a part of the main bar 4 is welded to a flange 6 of the steel beam 2.

The entire length of the buried main bar 4 is constrained by a steel plate 7, and the steel plate 7 reinforces the entire precast reinforced concrete portion 3.

A cotter 8 is provided on the ostium surface of the precast reinforced concrete portion 3 from which the main bar 4 is projected, and serves to increase the shear resistance with the reinforced concrete column 9.

Further, the bearing plate 1 is attached to the steel beam 2 in the vicinity of the wood mouth surface provided with the cotter 8 and on the wood mouth surface on the opposite side.
0 is welded. The pressure bearing plate 10 is welded between the upper and lower flanges 6 on both sides of the web 5, and the pressure bearing plate 10 on the cusp surface is located above the upper flange 6 and the lower flange 6.
It is projected on the lower side of each.

Next, the transmission of stress from the steel beam 2 to the precast reinforced concrete portion 3 will be described with reference to FIG.

The tensile side of the bending moment is (1) in the same figure.
As shown in (4), it is smoothly transmitted through the main reinforcement 4 of the precast reinforced concrete portion 3 welded to the flange 6.

The compression side of the bending moment is smoothly transmitted to the precast reinforced concrete portion 3 via the bearing plate 10 as shown in (1) of the same figure.

Further, in this portion, the steel plate 7 is wound to strengthen the restraining force of the precast reinforced concrete portion 3 to increase its bearing capacity and at the same time, the leverage allows the stress to be transmitted smoothly.

The shearing force is transmitted to the precast reinforced concrete portion 3 by the bearing capacity of the flange 6 having the web 5, as shown in (2) of the figure.

In the same manner as described above, the steel plate 7 wound around this portion strengthens the restraining force of the precast reinforced concrete portion 3 and increases the bearing capacity thereof, so that the stress transmission is effectively performed.

Further, FIG. 6 shows that all the main reinforcements 4 of the precast reinforced concrete portion 3 are screw reinforcements, and the ends thereof are attached to the bearing plate 10 by the nuts 11. With such a configuration, similarly to the above, the tensile stress of the bending moment can be smoothly transmitted to the precast reinforced concrete portion 3.

7 to 9 show the invention of claim 2, FIG. 7 is a vertical sectional side view of an end portion of a beam, FIG. 8 is a transverse plan view of the same, and FIG. 9 is C of FIG. It is a -C line sectional view.

As shown in FIG. 7, a part of the main bar 4 of the precast reinforced concrete part 3 is welded to the flange 6, and the main bars 4 on both sides which are not welded to the flange 6 are vertically connected to form a hoop shape. It was done.

The main bar 4 and the hoop-shaped main bar 4 welded to the flange 6 are constrained to the steel beam 2 by a steel plate 7.
Further, the other structure is the same as that of the first aspect of the invention.

[0032]

Since the main bar of the reinforced concrete part is attached to the flange of the steel frame beam, the bending moment acting on the end part of the steel frame beam is smoothly transmitted to the precast reinforced concrete part on the tensile side. Further, the bending moment is smoothly transmitted to the precast reinforced concrete portion on the compression side by providing the pressure bearing plate on the steel beam on the mouth end side of the rear end side of the precast reinforced concrete portion. Further, this transmission is more effectively performed by the lever action because the main bar is restrained by the steel beam with the steel plate.

A main bar embedded in a precast reinforced concrete part is restrained by a steel plate, and a part of this main bar is welded to a flange of a steel frame beam, and main bars on both sides which are not welded to the flange are respectively connected vertically to form a hoop shape. As a result, the bending moment acting on the steel beam end portion is smoothly transmitted to the precast reinforced concrete portion on the tension side. Further, since the pressure bearing plate is provided on the steel beam at the mouth end surface of the precast reinforced concrete portion on the rear end side, the bending moment is smoothly transmitted to the precast reinforced concrete portion on the compression side.
Further, this transmission is further effectively performed because the main bar is restrained by the steel beam with the steel plate.

By forming the precast reinforced concrete parts at both ends of the steel beam, it is possible to easily join the reinforced concrete columns.

By forming the precast reinforced concrete portions in which the ends of the main bars are projected at both ends of the steel beam, the steel beams can be embedded up to the surface of the reinforced concrete column, so that the force can be dispersed and transmitted.

The strength of the precast reinforced concrete portion is increased by restraining the entire length of the main reinforcement embedded in the precast reinforced concrete portion with a steel plate.

By providing the cotter on the tip side of the precast reinforced concrete portion, the shear resistance with the reinforced concrete column can be increased.

[Brief description of drawings]

FIG. 1 is a vertical cross-sectional side view of a beam having a reinforced concrete structure at its ends and a steel frame structure at its center.

FIG. 2 is a vertical sectional side view of an end portion of a beam.

FIG. 3 is a cross-sectional plan view of the end of the beam.

4 is a cross-sectional view taken along the line AA of FIG.

FIG. 5 (1) and (2) are conceptual diagrams showing stress transmission.

FIG. 6 (1) is a vertical sectional side view in which a main bar is screwed to a bearing plate,
(2) is a BB line sectional view of (1).

FIG. 7 is a vertical sectional side view of an end portion of a beam.

FIG. 8 is a cross-sectional plan view of the end of the beam.

FIG. 9 is a sectional view taken along the line CC of FIG. 8;

FIG. 10 is a vertical cross-sectional side view of a beam having a conventional reinforced concrete structure at the end and a steel frame structure at the center.

[Explanation of symbols]

 1 Beam 2 Steel Beam 3 Precast Reinforced Concrete Part 4 Main Bar 5 Web 6 Flange 7 Steel Plate 8 Cotta 9 Reinforced Concrete Column 10 Bearing Plate 11 Nut

Front page continuation (72) Inventor Takayuki Oi 1-7-1 Kyobashi, Chuo-ku, Tokyo Toda Construction Co., Ltd. (72) Inventor Nobuyuki Izumi 1-7-1 Kyobashi, Chuo-ku, Tokyo Toda Construction Co., Ltd.

Claims (4)

[Claims] 1. A precast reinforced concrete portion having a protruding end portion of a main bar is formed at both ends of a steel beam, and the main bar embedded in the precast reinforced concrete part is restrained by a steel plate, and a part of the flange is formed on the steel beam. Welded on, the support beam is provided on the steel beam at the back end side of the precast reinforced concrete part at the mouth end side. The end is a reinforced concrete structure and the central part is a steel beam. 2. A precast reinforced concrete part, in which a tip of a main bar is projected, is formed at both ends of a steel beam, and the main bar embedded in the precast reinforced concrete part is restrained by a steel plate, and a part of the flange is formed on the steel beam. End of the precast reinforced concrete part is provided with a bearing plate on the back end side of the precast reinforced concrete part. The part is a reinforced concrete structure and the center part is a steel frame beam. 3. The beam of claim 1 or 2, wherein the main bar embedded in the precast reinforced concrete part is constrained by a steel plate so that the end part is reinforced concrete and the center part is steel frame. 4. A beam having a reinforced concrete structure at the end and a steel frame structure at the center, according to claim 1 or 2, wherein a cotter is provided on the tip side of the precast reinforced concrete part.