KR20090127789A - Method for prestressing concrete girder using temporary loading and method for constructing bridge using thereof - Google Patents

Abstract

PURPOSE: A prestressing method of a concrete girder loading load for controlling excessive compression, and a bridge construction method using the same are provided to prevent applying excessive compressive stress to the concrete girder. CONSTITUTION: A bridge construction method using a prestressed concrete girder is as follows. A main tendon(11) is arranged on the tension side of a girder for removing load for controlling excessive compression, and a concrete girder(10) is manufactured. A part of the main tendon is strained and fixed on the ground by using an anchorage device(20). Prestress is applied to the concrete girder as much as excessive compressive stress is not generated, and is temporarily reduced by loading load for controlling excessive compression(12). The loading state is released in a state load is applied to the concrete girder so that tension stress is reduced by compressive stress.

Description

Method for prestressing concrete girder using temporary loading and method for constructing bridge using

1 is a schematic view of a conventional concrete girder placed in a fabrication site.

FIG. 2 is a state diagram showing stresses in a state in which prestressing is performed at the same time without prestressing the entire concrete girder main tension member shown in FIG.

3 and 4a to 4e are schematic views showing each step of the method for introducing the pre-stress and over-compression control load to the concrete girder and the method for constructing the concrete girder bridge using the same according to the present invention, respectively.

5 is a state diagram of the stress of the concrete girder showing the stress when the entire main tension material is prestressed simultaneously and the overcompression control load is carried out according to the present invention.

6A and 6B are diagrams corresponding to FIG. 3 as schematic views showing an embodiment in which the loading form of the overcompression control load is different in the present invention, respectively.

<Description of the code | symbol about the principal part of drawing>

10 ... concrete girder

11 ... main tension

12.Load for overcompression control

The present invention relates to a prestressing method of a concrete girder using a load for overcompression control and a method of constructing a bridge using the same, and more particularly, to introduce a prestressing to a concrete girder and to construct a bridge using the same, to manufacture a concrete girder In order to prevent excessive compressive stress from acting on the concrete girders due to the introduction of prestress at the same time, the pre-stress control load is applied to the concrete girders so that sufficient prestress compressive stress can be introduced when the concrete girders are in use. It relates to a method of applying prestressing and a method of constructing a bridge using the same.

1 is a schematic view of a conventional concrete girder 100 is placed in the manufacturing site, as shown in the drawing, in general, when producing the concrete girder 100 in order to construct a concrete girder bridge tension material 110 Arranged so that a predetermined prestressed compressive stress is introduced to the tension side of the girder 100. In FIG. 1, the tension member 110 is disposed inside the girder 100, but is illustrated by a solid line for explanation.

By the way, in such a conventional conventional concrete girder 100, in order to ensure that the tensile stress generated on the tension side when the load is applied to the pier later in the allowable range, often during the manufacture of the girder 100 Excessive prestress is sometimes introduced into the system. 2 is a state diagram showing the state in which the excessive compressive stress out of the allowable range on the tensile side of the girder 100 by introducing an excessive prestress at the time of manufacturing the concrete girder 100 in this way is shown.

In the case of the conventional concrete girder 100, in order to prevent excessive compressive stress beyond the allowable range on the tensile side of the girder 100 in the production of the concrete girder 100 in this way, the introduction amount of prestress should be reduced. If the prestressing amount is reduced, on the contrary, a sufficient compression force may not be applied to the girder 100 in the use state of the girder 100.

The present invention was developed in order to solve the above-mentioned problems, and the sufficient compression stress can act on the tension side in the load action state of the concrete girder while preventing excessive compression stress on the tension side during the production of the concrete girder. The purpose of the present invention is to provide a method of prestressing a concrete girder using an overcompression control load and a new method of constructing a concrete girder bridge using the same.

In order to achieve the object of the present invention as described above, in the present invention, as a pre-stressing method of a concrete girder functioning as a mold or a girder supporting a load in a bridge or a building structure, a main tension member is disposed on the tension side of the girder. Manufacturing a concrete girder on the compression side of the girder, in which bending compression stress is generated under a load action state, with an overcompression control load capable of temporarily canceling a predetermined amount of prestress by the main tension member; After tensioning the main tension member, the prestress by the main tension member is introduced into the concrete girder by fixing using the fixing device, and in parallel with this, the overcompression control load is loaded and then mounted using a releasable device. Introducing prestress into the concrete girder by temporarily reducing prestress caused by the main tension member; And after the load action, the overload control load is released from the load action state of the concrete girder such that only prestress by the main tension member acts on the concrete girder to cancel the tensile stress on the tension side of the concrete girder due to the load. There is provided a prestressing method of a concrete girder using an overcompression control load, comprising the step of removing the prestress reduction caused by the overcompression control load.

Further, in the present invention, the main tension member is disposed on the tension side of the girder, and on the compression side of the girder where the bending compressive stress is generated in the load action state, an overstress capable of temporarily offsetting a predetermined amount of prestress by the main tension member Manufacturing a concrete girder with a load for controlling compression; After tensioning the main tension member, the prestress by the main tension member is introduced into the concrete girder by fixing using the fixing device, and in parallel with this, the overcompression control load is loaded and then mounted using a dismountable device. Introducing prestress into the concrete girder by temporarily reducing prestress caused by the main tension member; Mounting the concrete girders between piers and shifts or between shifts and shifts; Installing a slab on top of the concrete girder; And the prestress by the main tension member acting on the concrete girder while the load transmitted by the slab acts on the concrete girder so that the tensile stress caused by the load is canceled by the prestress of the main tension member. A method of constructing a bridge using a prestressed concrete girder is provided by releasing a loading state of the overcompression control load to remove prestress reduction caused by the overcompression control load.

In the prestressing method and bridge construction method of the concrete girder according to the present invention as described above, the overcompression control load may be introduced over the center of the girder or a specific portion or the entire girder. In addition, the overcompression control load can be loaded in various ways than shown in Figure 6a and 6b at any position in the middle, top or bottom of the girder.

Hereinafter, a method for constructing a concrete girder bridge will be described in detail with reference to a method of prestressing a concrete girder according to a preferred embodiment of the present invention.

Figures 4a to 4e is a schematic diagram showing each step of the method of introducing prestress to the concrete girder and the method of constructing the concrete girder bridge using the same according to the present invention.

As shown in Figure 4a, first to produce a concrete girder 10 in the fabrication site. At this time, a conventional main tension member 11 for introducing a compressive stress by applying prestress as shown in the drawing is arranged on the tension side of the girder 10. In the present invention, the main tension member 11 is described above. Only the prestress is introduced so as to be within the allowable compressive stress without all the tension, and the target all prestress is introduced by applying the overcompression control load and prestressing the remaining tension members as shown in FIG. 4A. The main tension member 11 and the overcompression control load 12 may be loaded in any form anywhere outside the concrete girder 10, and the full tension material after the overcompression control load 12 is loaded first. Either tension (11) may be applied at the same time or the loads for prestress introduction and overcompression control may be loaded in any order.

In the present invention, the overcompression control load 12 is configured to be easy to install and dismantle in order to recover the erased prestressing as described later.

After the concrete girder 10 is manufactured in the state where the main tension member 11 is disposed as described above, after the main tension member 11 is tensioned, the fixing device 20 is mounted at both ends of the girder 10 as shown in FIG. 3. Prestress by the main tension material 11 is introduce | transduced into the concrete girder 10 by fixing using it. In parallel with this, the overcompression control load 12 is also loaded to temporarily reduce the prestress caused by the main tension member 11 in the concrete girder 10. At this time, the overcompression control load 12 is mounted using the releasable device 21 so as to release the mounting state later. 5 is a stress state diagram of the girder 10 showing the stress in the state in which the prestress is introduced by tensioning and loading both the main tension member 11 and the overcompression control load 12 in this way. As shown in FIG. 2, in the conventional girder, compressive stress exceeding the allowable compressive stress occurs at the lower edge of the center of the girder 10 due to the entire prestressing of the main tension member 11, but the overcompression control load 12 When the load) is applied, the opposite stress acts on the lower edge, and the compressive stress generated at the lower edge of the center of the girder 10 is within the allowable compressive stress. Therefore, in comparison with the conventional girder, in the present invention, sufficient prestress by the main tension member 11 can be applied to the concrete girder 10 within the range not exceeding the allowable compressive stress, so that the height of the girder 10 and the like can be adjusted. You can zoom out.

As such, when loading of the main tension member 11 and the overcompression control load 12 is completed, the concrete girder 10 is mounted on the site to be placed in a load action state. In the case of bridge construction, the concrete girder 10 is mounted between the bridge 30 and the bridge 31 or between the bridge 30 and the bridge 30, as shown in FIG. , The slab 40 is poured on top of the concrete girder 10. As such, when the slab 40 is placed and the concrete girder 10 is placed in a load action state, a tensile force is generated on the tensile side of the concrete girder 10 due to the action load, and at this time, the load state of the overcompression control load 12 is By canceling the prestressing reduction by the overcompression control load 12 is restored. That is, when the mounting device of the overcompression control load 12 loaded on the girder 10 is released, the loading state of the overcompression control load 12 is released, whereby the overcompression control load ( The prestress reduction by 12 is eliminated. Therefore, the pre-stress by the main tension member 11 acts on the concrete girder 10, and the tensile stress on the tension side of the concrete girder 10 generated by the working load is applied to the pre-stressing of the main tension member 11. Offset by the compressive stress. After the overcompression control load 12 is removed to reduce its own weight and recycle resources, it is mounted on another girder and reused.

As described above, in the present invention, when the concrete girder 10 is manufactured, the compressive stress acting on the tension side of the concrete girder 10 by prestressing the main tension member 11 is converted into the tensile stress by the overcompression control load 12. Temporarily reduce the pressure within the allowable compressive stress range, and remove the overcompression control load 12 in the actual loading state so that the compressive stress due to prestressing of the main tension member 11 acts to reduce the tensile stress due to the working load. It is offset enough.

Subsequent to the use state shown in FIG. 4E, additional operations to be performed in conventional bridge construction, such as paving work on the upper surface of the slab, installation of a firewall, and the like, are performed.

In FIG. 3, the overcompression control load 12 is illustrated as being mounted on the lower flange of the girder center portion, but the load of the overcompression control load 12 is not limited thereto. 6A to 9B are schematic views showing an embodiment in which the arrangement of the overcompression control load 12 is changed, corresponding to FIG. 3. As illustrated in FIG. 6A, the overcompression control load 12 may be disposed at the center portion of the trunk. In addition, the overcompression control load 12 may be disposed in the longitudinal direction of the concrete girder 10 with respect to the entire interval, or may be disposed in a portion of the interval or in the central portion of the interval. On the other hand, the overcompression control load 12 may be arranged by mounting on the lower flange of the concrete girder 10. FIG. 6B shows the overcompression control load 12 manufactured in a circular shape or supported by penetrating the girder abdomen or mounted on a lower flange including an upper flange top.

As such, the overcompression control load 12 may be loaded in various forms in various positions.

In the above description, the method of prestressing concrete girder according to the present invention has been described by illustrating a construction method of a bridge, but the present invention is not limited thereto, and the present invention may be applied to a structure or a construction site using prestressed concrete girder. have.

As described above, in the present invention, when the concrete girder 10 is manufactured, the compressive stress acting on the lower end of the span center portion of the concrete girder 10 by prestressing the main tension member 11 is applied to the overcompression control load 12. After reducing the tensile stress to be within the allowable compressive stress range, in the actual load action state, the over-compression control load 12 is removed so that the compressive stress due to prestressing of the main tension member 11 acts. This is enough to offset the stress.

Therefore, according to the present invention, the compressive stress due to the prestressing acting on the lower end of the span section at the time of manufacturing the concrete girder 10 is within the allowable compressive stress range, while in actual use state to offset the tensile stress due to the working load The effect of sufficient compressive stress is exerted, thereby reducing the girder cross section, such as reducing the height of the girder.

Claims (5)

As a prestressing method of the concrete girder 10, which functions as a mold or girder that supports the load in a bridge or building structure, The over-compression which arrange | positions the main tension material 11 at the tension side of the girder 10, and loads the overcompression control load 12 so that the prestress by the said main tension material 11 can be temporarily canceled by a certain amount. Manufacturing a concrete girder 10 with a control load 12 loaded; After the main tension member 11 is tensioned and fixed using the fixing device 20, prestress by the main tension member 11 is introduced into the concrete girder 10, and in parallel thereto, the overcompression control load 12 is loaded. Reducing the prestress effect by the main tension member (11) on the concrete girder (10) by the overcompression control load (12) by mounting using a dismountable mounting device afterwards; And After the load action, in the load action state of the concrete girder 10, only the prestress by the main tension member 11 acts on the concrete girder 10 to cancel the tensile stress on the tension side of the concrete girder 10 due to the load. And releasing the loading state of the overcompression control load (12) to remove the prestress reduction effect by the overcompression control load (12). The method of claim 1, The overcompression control load (12) is a prestressing control method of the concrete girder using the overcompression control load, characterized in that having a structure that is easy to attach and detach. The method according to claim 1 or 2, The overcompression control load 12 may be disposed in the center of the trunk or in the longitudinal direction of the concrete girder 10, and may be disposed in a portion of the trunk or distributed in the center of the trunk, as well as a quadrangle or a circle. It is also possible to manufacture in various forms such as oval, and can be mounted on the lower flange or fastened through the girder abdomen, as well as variously mounted on the top of the upper girder, the concrete using the over-compression control load How to control prestressing of girders. And a state (主) tendons (11) the girder (10) disposed on the tension side, and by loading the compression control loads 12 to be temporarily fixed amount offset by the prestressing due to the main tendons 11 of the Manufacturing a concrete girder 10 in a state where the compression control load 12 is loaded; After the main tension member 11 is tensioned and fixed using the fixing device 20, prestress by the main tension member 11 is introduced into the concrete girder 10, and in parallel thereto, the overcompression control load 12 is loaded. Reducing the prestress effect by the main tension member (11) on the concrete girder (10) by the overcompression control load (12) by mounting using a dismountable mounting device afterwards; Mounting the concrete girder 10 between a piers and shifts or between shifts and shifts; Installing a slab (40) on top of the concrete girder (10); And The tension of the concrete girder 10 generated by the load by allowing only the prestress by the main tension member 11 to act on the concrete girder 10 in a state in which the load transmitted by the slab 40 acts on the concrete girder 10. And removing the overcompression control load 12 by releasing the loading state of the overcompression control load 12 so that the tensile stress on the side is canceled by the prestress of the main tension member 11. Construction method of bridge using prestressed concrete girder. The method of claim 4, wherein The overcompression control load (12) is a bridge construction method using a prestressed concrete girder, characterized in that having a structure that is easily removable.

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