KR200167491Y1 - Apparatus for connecting continuously upper slab concretes of multi-span preflex composite bridge and represtressed preflex composite bridge by P.C steel wire P.C steel bar. - Google Patents

Abstract

The present invention independently constructs a prebeam beam or a leafrestrest preflex beam that combines steel I type girders with reinforced concrete or PC strands or PC steel rods, or independently at each shift of a multi-span bridge over two spans. In the case of placing the upper slab concrete so that the span is continuous, the load after the change to the continuous beam structure at each continuous coupling point in accordance with the change of the simple beam structure to the continuous beam structure system so that each span is continuous during construction. Since the parent moment acts on the upper slab concrete, tensile stress is generated. In this case, in general, the upper slab concrete of the continuous bonding point is a structure that does not sufficiently resist the tensile stress was a structural problem that is gradually damaged due to severe cracking of the concrete.

Accordingly, the present invention is a steel I-girder of each pair of simple beam beams adjacent to the continuous coupling point before placing the upper slab concrete 3 (before the change to the continuous beam structure system), as shown in Figures 3-6. Depending on the fixing part supported by the upper flange 8 of (1), the PC strand or the PC steel bar 9 is arranged in advance to adjust the initial stress, and then the upper slab concrete 3 is placed so that each span is continuous. The tensile stress due to the parent moment of the continuous bonding point is all burdened by the P. strand strand or P. rod (9), so that the upper slab concrete (3) of the continuous coupling point has no excessive tensile stress and the resulting cracking at all. Multi-span preplex composite girder bridges with P.C strands and P.C rods are provided for continuous connection of upper slab concrete.

Description

Apparatus for connecting continuously upper slab concretes of multi-span preflex composite bridge and represtressed preflex composite bridge by PC steel wire PC steel bar.}

The present invention relates to an upper slab concrete continuous coupling device using P.C strands and P.C steel rods of multi-span preplex composite bridges and leafyrest preflex composite bridges.

In constructing multi-span bridges with two or more spans, as shown in FIGS. 1 and 2, the beams 4 previously prepared on the ground are independently constructed on each of the spans on the alternating or pier 5, and then the beams 4. In the case of placing the upper slab concrete 3 to be integrated with), conventionally, the upper slab concrete 3 is also cut separately for each span and poured into a simple beam structure. Install the device (bridge bridge) or increase the amount of rebar used at the point of the boundary between the upper slab concrete (3), which is the reinforced concrete structure, and cast each bridge continuously. Attempts have been made to improve the running performance of a vehicle by suppressing the use of h).

At this time, when placing the upper slab concrete (3) in the simple beam structure system in which the simple beam (4) is independently installed for each span on the alternating or pier (5), that is, the construction so that each span is continuous In case of converting into continuous structure system, the parent moment (-M) is generated by the load after converting into continuous structure system at the continuous coupling point which is the boundary of each span.

Accordingly, the upper slab concrete 3 of the continuous bonding point generates a considerable amount of tensile stress and consequently cracks of concrete, as shown in (c) of FIG. 2, so that the breakage of the upper slab concrete 3 of the continuous bonding point is rapid. Progress.

Therefore, in order to alleviate the problems as described above, it is possible to increase the amount of tensile resistance reinforcing bar in the upper slab concrete (3) of the continuous coupling point, but in the narrow section of the upper slab concrete (3), It is well known that the limitations do not meet the permissible tensile stresses and permissible crack widths of conventional reinforced concrete structures.

In particular, the preflex beam (aka PF composite beam), or re-restrest preflex, is a simple beam beam combining steel I-girder (1) and reinforced concrete or PC strands together to reduce the height of the bridge and construct the bridge between long sections. When the upper slab concrete 3 is continuously combined with the beam 4 (aka RPF composite beam) as above, the parental moment (-M) of the continuous slab of the upper slab concrete (3) is very large because the mold height is low and the long span is long. The tensile stress of the upper slab concrete (3) and the cracking of the concrete are more serious problems. In general, the preflex beam or the reefrestrest preflex beam (4) can be used to increase the amount of tensile resistive steel. Multi-span continuous coupling of the upper slab concrete (3) is almost impossible.

The present invention is a multi-span upper portion of a preflex beam or a leafrest preflex beam (4), which is a simple beam member combining steel I type girders (1) and reinforced concrete or PC strands together. The PC slab or PC steel bar (9), which has superior resistance to reinforcement than the reinforcing bar, does not increase the use of tensile resistance steel in the upper slab concrete (3) of the slab continuous bonding point, and the preflex beam or leaf of the adjacent span at each point. The restrest preflex beams 4 are arranged to restrain the upper flange 8 of the steel I-type girder 1, and then the initial stress of each PC strand or PC steel bar 9 is adjusted to a certain size so that the upper slab concrete (3) is placed in succession for each span.

At this time, the dead weight before the upper slab concrete 3 is hardened, that is, before the upper slab concrete 3 is hardened, is a preflex beam or leaf-rest free between the independent spans in the simple beam structure where each point is not continuously coupled. It acts on the flex beam 4.

Therefore, due to the dead weight when placing the upper slab concrete 3, the simple beam structure preplex beam or the leafrest rest preplex beam 4 has the center of the beam as shown in (a) and (b) of FIG. At each point, the deflection is caused to cause rotational displacement of the beam end or to adjust the initial stress to a certain size, so that each PC strand is constrained to the upper flange 8 of the steel I-girder 1 or Since the PC steel bar causes a slight parental moment (-M), each PC strand or PC steel rod 9 is elongated (stretched) and stress is induced to naturally tension the PC steel wire or PC steel rod 9 in advance. The effect that the prestress stress like the one which carried out was introduced is produced.

Therefore, the tensile stress due to the parent moment at the continuous engagement point due to the load acting after the upper slab concrete 3 hardens is offset in advance before being transferred to the upper slab concrete 3, so that the tensile stress on the upper slab concrete 3 The cracks do not occur at all.

Figure 1 (a) and (b) is an exemplary view showing a conventional preplex synthesis type and leafrestrest preflex synthesis type,

Figure 2 (a) is a conventional preflex composite beam or leaf restraint preplex composite beam hypothesized on the alternating or pier for each span of the multi-span bridge, the moment (+ M ₁ ) of the simple beam structure by its own weight Degree,

(B) is a state in which the upper slab concrete is cast so that each span is continuous in Fig. 2A, and the moments (+ M ₃ , -M) are generated by the subsequent joining of the points,

(C) is the incidence of tensile cracking due to the parent moment (-M) of the upper slab concrete continuous bonding point,

(D) is a cross-sectional view taken along the line A-A of FIG.

(E) is a cross-sectional view taken along the line B-B of Figure 2 (a),

Figure 3 is a facility name showing the arrangement of the upper flange support fixing portion and the P.C strand or P.C steel bar of the steel I-girder for the upper slab continuous coupling according to the present invention,

4A is a side explanatory diagram of FIG. 3 according to the present invention;

(B) is an enlarged view of portion b of FIG.

(C) is an enlarged view of portion c of FIG. 4 (a),

5 is an enlarged view of the upper flange support fixing portion (a part of Figure 3) of the steel I-girder according to the present invention,

Figure 6 is a cross-sectional view showing the arrangement of the upper flange support fixture and the P.C strand or P.C steel bar of the steel I-girder for the upper slab continuous coupling of the present invention,

(A) is a cross-sectional view taken along line C-C of FIG.

(B) is a cross-sectional view taken along the line D-D of FIG.

(C) is a cross-sectional view taken along the line C-C of Figure 4 (preplex beam),

(D) is sectional drawing of the D-D line of FIG. 4 (for a preflex beam).

-Explanation of symbols for the main parts of the drawings-

1-steel type I girder, 2-lower flange concrete,

3-upper slab concrete,

4-preplex composite beam or leafrest rest preplex composite beam in simple beam state,

5-shift or pier,

6-preplex composite or leafy rest preplex composite with continuous top slab,

7-upper flange support fixing part of steel type I girder,

8-upper flange of steel type I girder, 9-PC strand or PC bar,

10-through hole, 11-reinforcement bulkhead.

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

3 and 4 are constrained to the upper flange of the steel I-girder between the adjacent prepreg beam or leaf restrest preplex beams of adjacent spans at each point portion prefabricated by a simple beam structure system over a multi-span according to the present invention. It is an explanatory view of arranging PC strands or PC steel bars as possible. Exemplary drawings FIGS. 5 and 6 are explanatory views of the support fixing part of the upper flange of the steel I type girder according to the present invention.

The present invention is a neighboring preplex when continuous coupling of the upper slab concrete (3) of the preflex composite beam or the leafrest preplex composite beam (4), which is a simple beam member independently constructed for each span in a multi-span bridge. The upper flange 8 of the steel I-type girder 1 of the composite beam or leafrest rest preflex composite beam 4 is provided with a support fixing part 7 having a through hole 10 and a reinforcing partition 11 formed therein. However, the upper flange (8) is made of a multi-layered, attached to both ends of each layer in a symmetrical direction to be installed so as to correspond to each other when installing the PC strand or PC steel bar (9).

Self-weight before the concrete is hardened by placing the upper slab concrete 3 by the PC strands or PC steel rods 9 assembled through the through holes 10 of the support fixing portion 7 in succession. Rotational displacement of the beam end part by deflection of the preflex beam or the leafrest preflex beam 4 of each span as a simple beam structure system as shown in FIG. A slight parental force (-M) generated in the PC strand or the PC steel rod 9 constrained by the upper flange 8 of 1) may support the elongation (elongation) generated in the PC strand or the PC steel rod 9. The upper slab concrete (3) continuous coupling device of preplex composite bridge or leafrestrest preflex composite bridge.

The support fixing portion 7 corresponds to the upper flange 8 between the preflex beams or the leaf restraint preflex beams 4 adjacent to each point in order to efficiently arrange the PC strands or the PC steel rods 9. It can also be arranged in pairs, two or several pairs.

On the other hand, the support fixing portion 7 is formed with a reinforcement partition 11 to effectively support the tension (stretching) of the PC strand or PC steel bar 9, the reinforcement partition 11 is a through hole Each through hole 10 is formed in three dimensions to support the tension of the PC strand or PC steel bar 9.

In this state, when the upper slab concrete 3 is continuously cast for each span, the preflex beam of each independent span, which is a simple beam structure system, until then by the dead weight (self-weight) of concrete at the time of placing (before the concrete is hardened) Alternatively, the center portion of the leaf restrest preflex beam 4 may cause deflection as shown in FIGS. 2A and 2B to cause rotational displacement of the beam end at each point, or Each of the PC strands or PC steel rods 9 constrained by the upper flange 8 generates some parental moments (-M), resulting in a certain amount of elongation (stretching), resulting in pre-stressing and the introduction of prestress stress. Will occur.

As described above, according to the present invention, since the preflex composite beam or the leafrest preplex composite beam 4 for reducing the height while lengthening the span is more effectively and securely coupled to the point portion of the upper slab concrete 3 over the multi span. At the continuous joining point, the tension cracking of the upper slab concrete (3) and the resulting damage are eliminated, thereby reducing the use of the bridge expansion joint (bridge bridge) for each span, and improving the stability. have.

Claims (1)

Steel I type girders (1) and reinforced concrete or PC strands are combined with them to prefabricate the preflex composite beam or leafrestrest preflex composite beam (4) made of simple beam members. Preflex beams that are independently placed on each bridge with simple beams on alternating and pier (5), and symmetrical between adjacent spans at points above each pier (5) to continuously cast upper slab concrete (3) Or one or two pairs or several pairs of support fixtures in which through-holes 10 and reinforcing partitions 11 are pre-installed in the upper flange 8 of the steel I-type girder 1 of the leafrestrest preflex beam 4. (7) of the multi-span preflex composite bridge and leaf restraint preflex composite bridge characterized in that the symmetrical installation and several PC strands or PC steel rods (9) are arranged depending on the support fixing portion (7) P. Cgang Upper slab concrete continuous coupling device by stranded wire and PC steel rod.