KR101305918B1 - Mould for precast girder - Google Patents

Abstract

The main object of the present invention is to form a girder hinged on the base to cure the girder, and after the girder curing, in the formwork device for precast girder to demold the girder outwards, the repeated use by mobility It is possible to provide a formwork for precast girders that is easy to install and dismantle, and has a forced stand that is effective for eliminating environmental pollution. The formwork is supported by the front and rear walls made of steel and the two steel walls connected to the thrust structure. Its mobility stand provides mobility, allowing it to be used repeatedly, and it is easily moved to the open field near the new bridge laying site for easy installation and dismantled after the bridge construction, and placed in the girder reinforcement network before placing concrete on the stand. Cam when tensioning the steel wire to give camber To the installation of the tension correspond to the camber given rod between both side walls of the stand to a precast girder formwork device for the modification concerns that wiping of the stand feature to prevent deformation of the stand caused.

Description

Formwork for precast girders {MOULD FOR PRECAST GIRDER}

The present invention relates to a precast girder formwork device for demolding the girder by standing up the formwork installed hinged on the base to cure the girder and tilting the form to the outside after curing the girder, and more particularly to the movable stand The present invention relates to a precast girder formwork for repetitive use of formwork, installation and dismantling of formwork, and the elimination of environmental pollution problems at the girder production site due to the application of non-concrete stands.

Precast girders are of eye type and inverted type. The eye girders are integrally formed with flanges at the top and bottom of the web, and the inverted girders are without the top flange.

Among the formwork devices for precast girders of any type, as shown in FIGS. 1 and 2, the hinges are connected by hinge shafts to the lower handles 2a of the formwork 2 to the handles 22 attached to both sides of the base 7. When preparing the fabrication, the formwork (2) is stood up, and when the cured girder is demolded, the formwork (2) is spread outwardly, and a separate dowel (9) is installed on both outer sides of the base (7) and the dowel (9) ) And the formwork standing-up means (6) are installed on the upper ledge (2b) of the formwork (2) to form the formwork (2) vertically when placing concrete on the girder and formwork (2) when demolding the cured girder. There is a thing to secure the demolding space by excluding the outside. The formwork 2 refers to the side formwork used to build both walls of the precast girder.

Until now, a thick and wide reinforced concrete foundation (1) was constructed for installation of formwork on the open ground or cilantro site near the bridge construction site, but the anchor bolt was buried where the base (7) and the handle (9) would be located. (7) and dowel (9) were installed and operated by tightening nuts. In the reinforced concrete foundation (1), a reaction force (5), a thrust head (3), and a tension jack (4) are installed outside the ends of the formwork (2) to tension the steel wire, thereby applying a camber corresponding to the design value to the precast girder. Will be given.

Reinforced concrete foundations are required to be removed after construction of the required number of precast girders for the bridge to be constructed, taking into account the landscape and environment surrounding the bridge. The first problem inherent in reinforced concrete foundations is that the operation period of the girder formwork is prolonged and the operating costs increase as the facility air and demolition air are included. Second, the debris of pour concrete when constructing reinforced concrete foundations, and the dust and noise generated when demolition of reinforced concrete cause environmental problems and cost concrete fragments. Next, reinforced concrete foundations are immovable and cannot be used repeatedly. It is no hassle to build a reinforced concrete foundation for precast formwork at every bridge construction.

In the case of new bridges, it is common to manufacture the number of precast girders at the same time as the bridge width per synagogue, so that the reinforced concrete foundation is also installed in the same number as the formwork for the precast girder. Frequent efforts, huge costs, and environmental countermeasures for the construction and demolition of the building are worthwhile.

On the other hand, the base of the above-described formwork for precast girders is a fixed type can not be adjusted in width. In order to produce precast eye girder or reverse girder with different widths with one set of eye type or reverse tee precast girders, it is necessary to change the width of the base to adjust the spacing of both sides. Formwork for cast girders is unfortunate because it is not possible to produce heterogeneous precast girders with a single formwork because the width of the formwork mounted base of the same standard is unchanged.

Therefore, in the present invention, in the formwork for the precast girder to form a girder hinged on the base to cure the girder, and after the girder curing, to form the girder by spreading the form outward, it is possible to repeat use by mobility It is intended to provide a formwork for precast girders that is easy to install and dismantle and has a forced stand that is effective even in solving environmental pollution problems.

It is another object of the present invention to provide a formwork for precast girders capable of producing heterogeneous precast girders of different widths with discontinued formwork.

The first problem is that the front and rear walls are made of steel and the two steel plates are connected to the formwork support stand, which is connected to the thrust structure. After installation and bridge construction, it can be easily dismantled and between the two walls of the stand to prevent deformation of the stand caused by the camber when tensioning the steel wire placed on the girder rebar network before placing the concrete on the stand. It is possible to achieve a formwork device for precast girder which eliminates the fear of deformation of the stand by installing a steel rod given a tension corresponding to the camber.

The second task is that the stand for performing the first task is to perforate the fastening hole in a constant pitch along the width direction on the top plate, and the base is installed in the base plate is divided into its width so that both formwork owns each A pair of stand members are formed by drilling a fastening hole at the same pitch as the fastening hole of the stand, and when the gap between the base members is increased according to the width of the precast girder to be manufactured, the fastening hole of the stand having the same center as the fastening hole is bolted. -It can be achieved by means of precast girder formwork which is fastened by fastening with nuts and inserting spacers corresponding to the space width in the space between the stand members.

Forced stands can be installed simply by placing them on flat grounds near the bridge construction site. Compared to the existing reinforced concrete foundation, the facility air is greatly shortened and the evacuation is very convenient. The steel stand is also mobile in itself, so that the formwork for the precast girders can be simply transferred to another bridge construction site or storage site for installation or storage and reused for subsequent bridge precast girders.

In addition, this forced stand may be deformed when the steel wire for precast girder is tensioned on the stand, that is, the stand may be wheeled in the opposite direction of the camber due to the reaction when applying the camber. Given a tension, a steel bar across the bottom of the walls on both sides of the forced stand prevents the deformation of the stand.

And since the base divided into the width direction can use the change in the formwork distance in the width direction on a forced stand, the mold of a single specification can also manufacture a different precast girder of different width.

1 is a front view of a formwork for precast girders installed on a reinforced concrete foundation
Figure 2 is a longitudinal side view of Figure 1 including a scene when demoulding a precast girder (hatching not shown)
Figure 3 is a front view when the precast girder formwork is installed on the forced stand of the present invention
4 is a longitudinal side view of FIG. 3 including a scene when demoulding a precast girder (hatching omitted)
5 is a reference diagram illustrating the possibility of deformation of the stand due to the camber of the precast girder;
6 is an exemplary view of fixing the steel rod to the wall of the stand.
7 is an exemplary view of a stand to which the variable width stand is applied;
8 is an application example of the variable width stand
9 is an illustration of a formwork for precast girder to which the truss stand is applied

In FIG. 3, the forced stand 10 is mounted in the order of the reaction table 5, the tensioner 4, and the thrust head 3 on the outer periphery of both ends around the formwork 2 for the precast girder. have.

Referring to FIG. 4, the forced stand 10 corresponds to a conventional reinforced concrete foundation, and both ends in the longitudinal direction are made of thick steel walls, and a steel bar 14 intersects between lower ends of both walls. As illustrated in FIG. 5, the steel bar 14 offsets the influence on the stand a when the steel wire c is tensioned to impart the camber d to the precast girder b so as not to be deformed (e). To protect, it is installed between the two walls with a given tension corresponding to the camber.

On the lower end of the wall, the sealing holes 13 are drilled at equal intervals on both sides of the center of the width of the forced stand 10, and both ends of the steel bars 14 penetrate the sealing holes 13 from the inside to the outside. The nut 30 is fastened and fixed at the outside of the wall as shown in FIG. 6. The end 14a of the steel rod 14 is given a lead suitable for fastening the nut 30.

If the conventional reinforced concrete foundation is built-in type, the forced stand 10 is mounted. Unlike the built-in reinforced concrete foundation, the stationary steel stand 10 can be manufactured simply by simply installing the formwork for the precast girder if the flat ground is formed, so that the precast girder can be manufactured in a short time. Formwork for precast girders can be installed, while withdrawals can be quickly transported to other locations for storage or transported to other bridge construction sites for reuse. In other words, the maneuverability of the precast girder formwork mounted forced stand 10 can be utilized to the maximum.

Since the forced stand 10 is excluded from the concrete, it is also very free from environmental pollution around the precast girder production site caused by concrete.

 Figure 7 relates to a modified embodiment for increasing the utilization value of the base on which the formwork is installed. Specifically, the fastening hole 15 is drilled at regular intervals along the width direction in the area where the base is installed in the upper plate of the forced stand 10, and the base is divided halfway around the width so that a pair of opposing base members ( 20) At the same time, the precast girder for forming the formwork 2 by drilling the fastening hole 22 having the same pitch as the fastening hole 15 with the fastening hole 15 at the bottom of each base member 20 is a precast girder of the standard specification. If the width is different from the width of the precast girder, the base member 20 on both sides is moved in the width direction by an equal distance, and the bolt-nut is fastened where the centers of the mutual fastening holes 15 and 22 coincide. To fix the base member 20.

The spacing between the base members 20 is smoothly cured on the bottom of the precast girder to be filled with the spacers 21. In order to stabilize the mounting posture of the spacer 21 caught in the gap between the base members 20, the fastening holes 23 and 24 are provided in the wall of the divided end side of the base member 20 and the wall of the spacer 21 which is external to the wall. Perforate to allow bolt-nut tightening.

In FIG. 8, the precast girders having the same height and lower flange dimensions but different widths use the spacer 21 that adjusts the separation distance between the base members 20 according to the above-described method and matches the separation distance. Heterogeneous eye and different width precast girders and heterogeneous reverse tee precast girders can all be manufactured in a single precast formwork.

FIG. 9 illustrates a modified forced stand 10a when the thick steel wall is replaced by the lattice-shaped leg 16 in the above-described forced stand 10. In this case, the sealing hole 13 is also drilled in the longitudinal direction of the forced stand at the lower end of the outer leg 16 in the same manner as the above-described steel plate wall, and ends the end of the steel bar 14 from the inside of the forced stand 10a to the outside. After passing through the steel rod 14 to offset the camber of the precast girder, the nut is fastened to the end of the steel bar 14 exposed out of the rod 13.

The forced stand 10a according to the modified embodiment can be lighter than the forced stand 10 having a steel wall, and gives a visually cool feeling.

10: forced stand
11: wing
13: sewing
14: steel rod
15,22,23,24: Fastener
16: outskirts
20: Stand member
21: Spacer

Claims (3)

The bottom handle 2a of the formwork 2 is hingedly connected to the handle 22 attached to both sides of the base 7, and the separate handles 9 and the formwork 2 installed on both sides of the base 7 are provided. The reaction stand (5), the tensioner (4) and the thrust head (3) are arranged on both sides of the die standing-up means (6) and the formwork (2) installed between the upper claws (2b) of the Forced stand for precast girder, which crosses longitudinally the sealing hole 13 perforated in the lower end of both steel plate walls, and then tightens the nut 30 to the end 14a of the steel bar 14 which penetrates. 10) to enhance mobility and repeatability,
The steel stand 10 is a fastening hole 15 is drilled at a constant pitch along the width direction in the area of the formwork 2 in the upper plate, the base on which the formwork 2 is mounted, the opposing base member bisecting the width 20, but a spacer 21 is inserted into the bottom of the base member 20, the fastening hole 22 corresponding to the fastening hole 15, and spaced apart according to the width of the precast girder. Formwork for precast girders.
2. The formwork for precast girders according to claim 1, wherein the steel rods (14) are tensioned corresponding to the cambers of the precast girders.
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