KR20000054500A - Construction method that introduces compressive stress to bottom plate concrete and bottom moment flange of parent section by using and adjusting the descending and rising process of end point in short span and multi span composite structures - Google Patents

Abstract

In the construction method of short span composite structure, one end is treated as fixed point and the other end is moved point and the moving point is lowered and raised so that the compressive stress is applied to the bottom flange of the base plate concrete and the constant moment section. Construction method that introduces compressive stress to the bottom flange of the parent section section and the bottom flange section by using and adjusting the descending and rising processes of the end points in the short span and multi span composite structures to be introduced.

In the construction method of multi-span composite structures, the end points are lowered in the short span and multi-span composite structures in which the compressive stress is introduced into the bottom plate concrete of the inner point and the lower flange of the constant moment section by lowering and raising the alternating points at both ends. Construction method to introduce compressive stress to the bottom plate concrete and the constant moment section bottom plate by using

In the short span and multi span composite structures that can be applied to the preplex composite, steel box composite, and PSC composite structures, the descending and rising processes of the end points are used and controlled, and the bottom plate concrete and the static moment sections Construction method that introduces compressive stress to lower flange

Description

Construction method that introduces compressive stress to bottom section concrete of parent section section and bottom flange section by using and adjusting the descending and rising process of end point in short span and multi span composite structures.

The present invention relates to the construction method of the short span and multi span preflex composite type, PSC composite type, steel box type composite structure, and the prior art in the case of a short span Korean Laid-Open Patent Publication No. 0250937 (hereinafter referred to as "cited invention 1") "Manufacturing method of simple beam type preplex composite beam using supporting point", and in case of multi span, "Prestress beam composite beam for continuous beam", which is published in Korean Patent Publication No. 105754 (hereinafter referred to as "quoting citation 2") and using the same Construction of prestressed continuous composite beam structures.

1 shows a process for producing a synthetic form of Cited Invention 1. Referring to the invention cited with reference to the drawings as follows.

Figure 1a shows the lower casing concrete in the state of loading steel beams with pre-flection loads, cures them, mounts them between shifts, installs branch points in the center of the bridge, and compresses stress loss due to creep and dry shrinkage of the initial concrete. This is a state diagram in which the branch point is raised to make up, and the compressive stress is introduced into the lower casing concrete. FIG. 1b illustrates a process of placing and curing the upper deck concrete and the abdominal concrete with the branch point raised. Figure 1c is a state diagram to remove the branch after curing the top plate concrete and the like.

The above-mentioned prior art cited invention 1 has to install a branch point in the center of the beam to apply an upward load. Especially in a high space, the traffic flow under the bridge with expensive additional costs due to the installation of a copper barrier. It has the disadvantage of obstructing and making construction poor. In addition, Cited Invention1 has the additional usability that the cross section of the composite type must be enlarged due to the maximum static moment generated at the center of the beam because the whole bridge behaves as a simple beam system, which causes excessive deflection at the center of the beam. The problem also acts as a disadvantage. In addition, the bridge mechanism, which acts as a medium for transferring the load of the upper structure, is composed of a hinge point that allows rotation only and a roller point that can rotate and move, so that the safety of the superstructure is continually maintained. Not only must they be used, but they can be fatally damaged in an earthquake.

2 and 3 show the process for producing the synthetic form of the Cited Invention 2.

First, Figure 2 is a construction method of a two-span continuous structure by connecting the preflex composite beam made by the span according to the design of the continuous beam at the second point and then mounting the second point to add a compressive stress to the lower casing concrete (See FIG. 2a), and after curing the bottom plate concrete covering the upper flange of the rigid section of the section where the parent is generated (see also FIG. 2b), the raised point is lowered (see also FIG. 2c). Compressive stresses are to be introduced into the deck concrete to withstand the parent, and the rest of the deck concrete is poured (see also 2d) to complete the complete two-span continuous prestressed composite beam.

3 is for the construction method of the three-span continuous structure. The second point follows the same method as the two-span continuous structure. The next process is to raise and lower the bottom point concrete by placing and lowering the third point again. Complete three span continuous prestressed composite beam.

Prior art cited invention 2 described above is likely to cause the occurrence of construction joints due to the time difference between the concrete slab in the positive and secondary moment section, and the lifting and lowering of the point on the pier, not the shift adjacent to the land, that is, the second It has to be done at the branch and the third branch, which has the disadvantage of inconvenient work and the risk of safety accident.

The present invention has been devised for the purpose of solving the conventional problems as described above, in order to achieve the above object, the short span is to convert the conventional hinge point to the fixed end point form, and the remaining mobile end is lowered and raised, multi-span Through the process of lowering and raising the points of the bridges, that is, both ends, the present invention aims to propose a realistic, practical, economical new method of introducing compressive force to the upper deck concrete of the parent section and the lower flange of the composite type.

1 is a flow chart of the construction of the short span preflex composite type according to the existing invention

2 is a construction flowchart of a two-span continuous preflex composite type according to the existing invention

3 is a construction flowchart of the three-span continuous preflex composite type according to the existing invention

4 is a diagram illustrating a connection state between a composite type and an alternating type for making a fixed point of a short span preflex composite type according to the present invention;

FIG. 5 is a diagram illustrating a connection state of a composite type and an alternating type for making a fixed point of a short span steel box type composite type according to the present invention; FIG.

6 is a diagram illustrating a connection state of a composite type and an alternating type for making a fixed point of a short span PSC composite type according to the present invention;

7 is a construction flowchart of the short span composite structure of the present invention

8 is a construction flowchart of a two-span continuous composite structure of the present invention

9 is a diagram illustrating the connection state of a beam at an internal point in the construction of the multi-span continuous composite structure of the present invention

10 is a construction flowchart of the three-span continuous composite structure of the present invention

In the short span and multi span composite structures of the present invention, a construction method for introducing a compressive stress to a bottom flange of a parent section section and a bottom flange section by using a descending and rising process of an end point is described above. In order to solve various problems, the short span composite type converts the existing hinge point to the fixed end point and lowers and raises the other moving point to obtain a more economic cross section than the cited invention 1, and in the case of the multi span bridge piers In order to reduce the risk of safety accidents caused by the work of raising and lowering the internal points located on the upper and lower points of the shift, the manufacturing process will be described with reference to the drawings. Here, the construction method of the present invention is applicable to both the preplex composite type, PSC composite type, and steel box composite type.

First, Figure 4 shows the connection state between the alternating portion (1) and the preflex beam (2) to simply mount the preflex beam produced by the simple beam between the alternating and to make one end fixed point. First, bury the H-shaped steel (3) on the abutment (1), weld the connecting plate (4) for connection with the lower flange of the beam on it, and then completely connect the lower flange of the beam by bolt (5) or welding. (See also Figure 4a). Here, in the lower concrete of the alternating abutment (1), the chest wall (7) and the preflex beam (2), the reinforcing bar (6) was pulled out in advance and the seat (1), the chest wall (7) and the beam ( The rest of 2) of the lower lower flanges and the abdomen are then cast together to allow them to act as complete anchorage points (see also part 4b). In this case, the reinforcing material is installed in the composite mold and reinforced, and the studs 9 are installed in the abdomen as well as the upper flange steel to enhance the composite effect with the concrete. 4C shows a plan view of the shift.

FIG. 5 is a case of a steel box-type composite structure, which shows the connection state between the alternating portion 1 and the steel box type 2 to simply mount the steel box type between the shifts and make one end a fixed end point. As in the case of FIG. 4, first, the H-shaped steel 3 is buried in the seat 1, and the connecting plate 4 for connection with the lower box flange is welded thereon, and then the lower box flange and bolts 5 are welded. Or by welding (see FIG. 5a). Here, the reinforcing bar (1) and chest wall (7) by retracting the reinforcing bar (6) in advance by placing concrete with the upper floor plate and the seat (1) and chest wall (7) and the box-shaped abdominal and lower flanges together It can serve as a complete anchor point (see also part 5b). Here, the reinforcement (8) is installed in the steel box type to reinforce and the studs (9) are installed in the abdomen as well as the upper flange steel to enhance the composite effect with concrete.

FIG. 6 shows the connection state between the alternating portion 1 and the PSC beam 2 in order to make the one end fixed by simply mounting the PSC beam between the shifts in the case of the PSC composite type. As in the case of FIGS. 4 and 5, first, the H-shaped steel 3 is buried in the abutment portion 1, and the connecting plate 4 for connection with the PSC beam lower flange is welded thereon, and then the lower flange of the PSC beam. The plate embedded in concrete is completely connected by welding (see Fig. 6a). Here, the reinforcement (1), chest wall (7) and the reinforcing bar (6) in the PSC beam are pulled out in advance, and the abdomen and the lower flange of the scaffold (1), the chest wall (7) and the PSC beam together with the upper base plate. Placing concrete allows it to act as a complete anchor point (see also part 6b).

7 is a state diagram showing the construction process of the short span composite structure.

FIG. 7a shows a process of introducing additional compressive stress into the lower flange by lowering the opposite moving point instead of the fixed point and the resulting moment diagram.

FIG. 7b shows a state in which the bottom plate concrete is poured while the moving point is lowered and a moment diagram thereof.

In FIG. 7c, after the bottom plate concrete is cured, the lowered moving point is raised to introduce a compressive stress corresponding to the parent moment toward the fixed end point into the bottom plate concrete. In the case of Figures 7 a, b, and c, tensile stress is generated in the lower flange of the constant moment section, which corresponds to about 50 to 60% of the compressive stress introduced at both ends due to the increased stiffness after synthesis. As a result, a compression prestressing effect of about 30 to 40% is obtained.

In the case of the short span composite structure of the present invention, due to the large moment of the fixed point portion, the section about 0.1L from the fixed point end portion can be expanded to the cross section by increasing the cross section.

8 shows the construction process of the two-span continuous composite structure according to the present invention.

Contrary to the fact that Cited Invention 2 raises the second point, which is the inner point, to introduce additional compressive stress into the lower flange of the constant moment section, the present invention provides the preflex beam or PSC beam manufactured by the simple beam shape at the inner point. The same effect is obtained by connecting as shown in Fig. 9b and lowering the points at both ends which are alternate sides (see also Fig. 8a).

FIG. 8b shows a state in which the bottom plate concrete is poured while the points at both ends are lowered and a moment diagram thereof.

8c raises both end points lowered after curing of the bottom plate concrete to introduce compressive stress corresponding to the tensile stress occurring at the internal point portion after the synthesis into the bottom plate concrete. In the case of a, b, and c of FIG. 8, tensile stress is generated in the lower flange of the constant moment section, which corresponds to about 50 to 60% of the compressive stress introduced at both ends due to the increased stiffness after synthesis. As a result, a compression prestressing effect of about 30 to 40% is obtained.

FIG. 9a shows a detailed view in which two beams are connected by connecting plates 4 and bolts 5 at internal points in the preplex composite type.

In the case of Cited Invention 2, the bottom plate concrete of the parent section section is poured after the point is raised, while the inner concrete joint concrete 10 is placed, whereas in the present invention, the inner point is lowered before the points at both ends are lowered. The secondary joint concrete 10 is poured.

FIG. 9b shows a detailed view in which two beams are connected at an internal point in the case of the PSC synthesis type. When manufacturing each PSC beam, bolts 5 are inserted into the upper flange concrete in advance, and continuity is achieved using the connecting plate 4 when connecting the beams. The beams are also connected to the lower flanges using connecting bars. In this case, the lower flange of the inner branch portion is the compression side, so the role of the connecting reinforcing bar is small, but it is intended to stabilize the entire composite type. In addition, the connection jaw (11) is installed on the neutral axis of the beam for the convenience of the connection work and the non-shrink mortar is filled in the gap.

Steel box type composite type is easier to apply the method of the present invention because there is no connection portion in the inner point.

Figure 10 shows the construction process of the three-span continuous composite structure according to the present invention.

Similarly, unlike the invention in which the cited invention 2 raises the second point and the third point, which are internal points, in order to introduce additional compressive stress to the lower flange of the constant moment section, the present invention simultaneously lowers the points at both ends of the alternating side. Effect (see also 10a).

FIG. 10b shows a state in which the bottom plate concrete is poured while the points of both ends are lowered, and a moment diagram thereof.

10c raises both end points of the bottom plate concrete, which is lowered after curing, to introduce compressive stress corresponding to the tensile stress generated at the internal point after the synthesis into the bottom plate concrete. In this case as well, tensile stress is generated in the lower flange of the constant moment section, which corresponds to about 50 to 60% of the compressive stress introduced at both end points due to the increased stiffness after synthesis. You will get some compression prestressing effect. In the case of the 3-span continuous composite structure of the present invention, due to the structural characteristics of the continuous beam, the static moment generated in the inner span is only about 1/5 as the absolute value of the maximum moment generated in the inner point portion. On rise, it will have sufficient compressive stress even without the introduction of additional compression prestressing.

In the case of short span, unlike the correction structure of the simple beam system, the invention of the present invention is a primary misalignment system of the fixed end of the other end, and the moment is distributed to the alternating points at the fixed end point where a large moment may be generated. As a result, the burden on the external force of the beam is reduced, and a reduction effect and an extension effect of about 20% can be expected in the height of the mold and the plane, resulting in a more economical cross section. In addition, the number of expansion joints and lower seating devices can be reduced by integrating the chest wall and the bottom plate concrete of one shift that is treated as a fixed end point, which can achieve excellent effects in terms of maintenance. Due to the large energy dissipation effect, the shock resistance can also be excellent.

In the case of multi-span, the work of lowering and raising the point is carried out alternately, that is, on the land, so it is superior in convenience as well as safety, and the bottom plate concrete is laid at the same time, so that there is no concern about construction joint in the existing construction method.

Claims (3)

In the construction method of short span composite structure, one end is treated as fixed point and the other end is moved point and the moving point is lowered and raised so that the compressive stress is applied to the bottom flange of the base plate concrete and the constant moment section. Construction method that introduces compressive stress to the bottom flange of the parent section section and the bottom flange section by using and adjusting the descending and rising processes of the end points in the short span and multi span composite structures to be introduced. In the construction method of multi-span composite structures, the lower points of alternating ends of both ends are lowered and raised, so that the end points are lowered in the short span and multi span composite structures that introduce compressive stress into the bottom plate concrete of the inner point and the lower flange of the constant moment section. Construction method to introduce compressive stress to the bottom plate concrete and the constant moment section bottom plate by using Claims 1 and 2 in the parent section by using and adjusting the descending and rising process of the end point in the short span and multi span composite structure that can be applied to the preplex composite, steel box composite, PSC composite structure Construction method that introduces compressive stress to bottom plate concrete and bottom moment flange