KR20020012670A - A Bridge Establishing Method Using Fabricated Jack Support Unit - Google Patents

Abstract

PURPOSE: A slab installation method of a rahmen bridge, a slab bridge and a girder bridge using a prefabricated jack bearing device is provided to heighten convenience by excluding a concrete foundation work by processing a construction work without using an existing timbering. CONSTITUTION: A slab installation method of a rahmen bridge, a slab bridge and a girder bridge using a prefabricated jack bearing device comprises the steps of: installing a pier and an abutment temporarily at regular intervals on a space for installing a bridge; installing a prefabricated jack bearing device(300) to the upper part of the pier and the abutment; placing a hydraulic jack and a cross beam on a bearing plate body of the prefabricated jack bearing device(300) and installing a form supporter(130); installing a slab(150) temporarily by using the form; and removing the jack, the cross beam, the prefabricated jack bearing device(300) and the form supporter(130).

Description

Slab installation of bridge ramen bridge, slab bridge and girder bridge using prefabricated jack support device {A Bridge Establishing Method Using Fabricated Jack Support Unit}

The present invention relates to a method for manufacturing a slab that is the upper plate structure of the bridge.

In general, there are many cases of the bridge installation method, the most widely used method is the method of completing the top plate of the bridge using a number of supports after the construction of the bridge and the shift.

In other words, in the conventional bridge construction method of curing concrete to form the upper plate of the bridge, a plurality of supports are erected in a conventional manner, the formwork housing is supported on the upper part, the reinforcing bar is reinforced to the upper part, By curing the slabs of the legs, and later dismantle these temporary objects to complete the upper plate of the legs.

However, if the ground is soft, the ground must be cleaned to install the support, and in addition, the foundation concrete is required, so that the foundation period is added and the construction period is increased, and when the slab construction is completed, the foundation concrete is later discarded. As it must be processed as a product, it is an additional factor of construction cost.

In addition, since the support for supporting the formwork is very dense, it is almost impossible to correct it when it is not balanced in the construction process, thus causing a problem leading to the form collapse accident.

In particular, when there are obstacles such as rivers and overpasses, and obstacles such as sewer pipes or cables, the support is not easy to use, and thus the construction is impossible. If the height of the bridge is more than 10M, it becomes a very uneconomical method, and in the case of rain or heavy rain, there is a problem that the construction is difficult and complicated, such as the bottom surface of the bridge sinks and needs to be reinstalled.

Meanwhile, in another conventional example, when installing a bridge that crosses a road with a traffic volume, a H-beam between them while supporting a temporary vent similar to the shape structure of a scaffold frame is installed around a shift or a pier, avoiding the road. After the hypothesis was to install the formwork.

However, in this case, the ground clearance and foundation concrete work on the bottom of the shift or bridge pier is also essential to support the temporary vent, there is a problem of waste treatment, and also difficult construction of rivers and elevated road obstacles .

In addition, temporary construction and H-beams are difficult to install due to overweight, the higher the bridge is uneconomical, there is a fear that the bottom of the base concrete during heavy rain is swept away by the soil.

The present invention is to solve the above problems,

By installing a prefabricated support device (jack support device) on a bridge or piers, installing a formwork support on the prefabricated support device, and installing the formwork on the formwork support, the work is carried out without using existing clubs. The purpose is to provide the convenience of not having to proceed with concrete work.

In order to achieve the above object,

The present invention provides a pier and alternating construction process for constructing bridges and shifts at regular intervals in a space for constructing a bridge;

A jack support installation process for installing an impression jack support device on an upper portion of the pier and the shift;

A mold support installation step of placing a jack and a cross beam on the support plate body of the jack support device and installing a form support on the upper portion thereof;

Formwork installation process for installing the formwork on the formwork support;

A slab construction process of installing a slab using the formwork;

When the slab hypothesis is completed in the above process is characterized in that the demolition process of removing the jack, crossbeam and jack support device and formwork support.

1 is a pier and alternating construction process diagram in the present invention.

Figure 2 is a prefabricated jack restraint construction process diagram in the present invention.

Figure 3 is an impression jack and formwork supporting process of the present invention.

Figure 4 is a formwork installation process of the present invention.

5 is a slab temporary process of the present invention.

Figure 6 is a jack dismantling process of the impression in the demolition work of the present invention.

Figure 7 is a prefabricated dismantling process diagram of the demolished work of the present invention.

Figure 8a is a block diagram of the prefabricated jack support device of the present invention.

Figure 8b is a first embodiment of a prefabricated jack support device configuration of the present invention.

Figure 8c is a second embodiment of a prefabricated jack support device configuration of the present invention.

Figure 9 is a third embodiment of a prefabricated jack support device configuration of the present invention.

10 is a state in which the formwork support of the present invention is installed.

Figure 11a is a fourth embodiment of a prefabricated jack support device configuration of the present invention.

11B is a state diagram in which the present invention is applied to a ramen bridge.

12 is a general plate-shaped bridge configuration.

Figure 13 is a general PC beam bridge configuration diagram.

14 is a general steel box bridge configuration diagram.

Figure 15a is a configuration diagram of the PC beam bridge installation of the present invention.

15B is an enlarged view of a portion of a PC beam bridge of the present invention.

Fig. 15C is another installation state of the PC beam bridge of the present invention.

Figure 16 is a plate-shaped bridge installation state of the present invention.

Figure 17 is a steel box bridge installation state of the present invention.

Explanation of symbols on the main parts of the drawings

10: vertical connecting plate 20, 30: base plate

40: support plate 50: support hardware

100: pier 110: impression hydraulic jack

120: crossbeam 130: formwork support

140: formwork 150: slab

160: tension jack 170: wire

200: shift 210: vertical connecting plate

220: support piece 230: reinforcement piece

300: prefabricated jack support device 400: plate bridge

500: PC beam bridge 600: Steel box bridge

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

1 to 7 illustrate the Slavic bridge hypothesis method according to the present invention.

First, FIG. 1 illustrates a temporary construction of a bridge 100 and a shift 200, and the present invention simultaneously represents a situation in which existing installations are impossible due to the presence of rivers or obstacles.

However, it is a matter of course that the present invention can be used irrespective of whether or not existing installations are possible.

Figure 2 shows the installation of the prefabricated jack support device 300 on the pier and the alternating top after the construction of the pier 100 and alternating 200 in the present invention, where the prefabricated jack is installed on the pier 100 The supporting device 300 is formed at right angles so as to be placed on one side of the pier upper width direction as shown in FIG. 8A, and has one side base plate having horizontal connecting plates 10 extending at a predetermined length and width at both horizontal ends thereof. 20,

The other base plate 30 having horizontal connecting plates 10 integrally connected in a shape corresponding to the one side base plate 20 and placed on the other side of the piercing upper width direction at a position opposite to the one base plate 20. )and,

A pair of supports having a base plate 40 is fixed to the outer corner of each of the one side and the other base plate 20, 30 and protrudes horizontally on the outside of the one side and the other base plate (20, 30), respectively. It consists of the hardware 50.

In the above base plate 20, 30 can be completed by assembling at the installation point after fabrication in the state cut in a straight line with the pier shaft as shown in Figure 8b, or cut in a direction perpendicular to the pier shaft as shown in Figure 8c It can be completed by assembling at the installation point after each manufacturing in the state.

In the slab bridge slab installation process of the present invention, since the space to be assembled on the side is not secured, the support device is manufactured in the state of cutting in the direction of the pier shaft and placed in the upper part of the pier, and then at the front and rear portions of the pier. Assemble and complete.

Since the pair of supporting devices cannot be installed in the shifting part 200, the jack supporting device 300a having one supporting plate body 40 having the same shape as that of FIG. 9 is installed. The prefabricated jack support device 300a having one support plate body 40 on the upper surface is bolted and coupled to the upper surface of the shift 200.

3, after the assembly of the prefabricated jack support units 300 and 300a is completed as described above, the hydraulic jack 110 is installed on the jack support devices 300 and 300a, and the cross beam is provided on the hydraulic jack 110. 120 is installed, and shows that the formwork support 130 is installed on the crossbeam 120.

The cross beam 120 supports the form support 130, and at the same time the cross beam 120 is raised by the pressure of the hydraulic jack 110 for raising the role of the form support 130 to be constant. Do it.

When the prefabricated jack support device 300, 300a, the lifting hydraulic jack 110, the crossbeam 120 and the form support 130 as described above is completed as shown in FIG.

Subsequently, the formwork 140 as shown in FIG. 4 is placed on the formwork support 130, and as shown in FIG. 5, the reinforcement and concrete pouring process is completed to install the slab 150.

As described above, when the construction of the slab 150 is completed as described above, as shown in FIG. 7, the prefabricated jack support devices 300 and 300a are removed from the bar, and the removal order is the prefabricated jack support devices 300 and 300a. Detach the support hardware 50 and the support plate body 40 is fixed to protrude at right angles from the prefabricated jack support device (300, 300a) and then remove the formwork support (130).

At this time, removal of the formwork support 130, as shown in Figure 6, the tension jack 160 is installed on the upper slab 150 and the sewage hole of the slab 150 from the tension jack 160 (not shown) By using the wire 170 penetrating through) to fix the formwork support 130 to a certain height can be utilized to check the slab construction status and workbench.

When using the formwork support 130 as described above is used when the bridge is relatively high, the low bridge is to remove the formwork support 130 immediately while removing the jack support device (300, 300a) as shown in FIG. do.

On the other hand, the slab bridge as described above can be assembled by mounting the prefabricated jack support device 300 on the pier because the slab 150 is poured after installing the bridge device (1), but the ramen bridge does not install the bridge device separately Since the slab is cast on the pier, other methods should be applied to lay the slab of the Ramen bridge without applying the existing club.

To this end, in the present invention, when installing a piers or shifts, anchor bolt 240 is installed on the upper surface, and a vertical connection plate is fixed to the anchor bolt, and a jack support device for installing a support piece and a reinforcing beam on the vertical connection plate. It will be fixed.

That is, the jack support device 300b to be used in the ramen bridge is made of a vertical connecting plate 210, the support piece 220 and the reinforcing beam 230, as shown in Figure 11a, the jack support device ( When the installation of 300b) is completed, the formwork support 130 is installed thereon, and the slab is poured on the formwork support 130.

When the slab casting of the ramen bridge as described above is finished as shown in Figure 11b, in the subsequent demolition process is the same as the slab bridge.

On the other hand, in the construction form of the bridge can be largely divided into slab bridges and girder bridges, in the above-described form of the present invention applied to the slab bridges, the following describes the implementation of the formwork by applying the present invention to the girder bridge Shall be.

First, the general girder bridge is a plate-shaped bridge 400 in which the steel plate 410 supports the slab as shown in FIG. 12, and the PC beam bridge 500 in which the PC beam or the T-beam 510 supports the slab as shown in FIG. 13. And, as shown in Figure 14, the steel plate box 610 can be largely divided into a steel box bridge 600 supporting the slab, in the girder bridge as described above, all the separate brackets 420 for the formwork placing process There was an inconvenience to be installed at regular intervals.

That is, the plate-shaped bridge 400 is installed on both sides of the steel plate 410 as shown in Figure 12 and the formwork to the upper surface of the bracket 420 and the steel plate 410 after installing the concrete After curing the slab 430 was completed, as shown in Figure 13, the PC beam bridge 500 also installed brackets 520 on both sides of the support beam 510, the bracket 520 and the support beam (510) After installing the formwork to the upper surface and curing the slab 530 was completed, the steel box bridge 600 also installed brackets 620 on both sides of the steel box 610 as shown in FIG. After installing the formwork to the bracket 620 and the upper surface of the steel box 610, the concrete was cured to complete the slab 630.

Therefore, in order to complete the slab of the girder bridge as described above, since the brackets 420, 520, and 620 should be installed at a predetermined interval, not only a lot of time is required for the slab construction, but also the brackets 420, 520, and 620 with human hands. Since it must be installed one by one, there was a problem that accidents occur very frequently of workers.

The present invention is to solve the above problems, instead of installing the bracket as the formwork support means to install the formwork support on the bridge axis to support the formwork, the formwork support is installed on the piers or shifts Prefabricated brackets and impression jacks were used.

That is, the slab installation process using the prefabricated bracket and the impression jack of the present invention, the bridge and alternating hypothesis step of the construction of the bridge and alternating at regular intervals in the space to build the bridge;

A jack support device installation step of installing an impression jack support device on an upper portion of the pier and the shift;

Placing the jack and the cross beam on the support plate body of the jack support device, and installing the formwork support on the upper part of the formwork supporter for installing the formwork support with the same height between the beams;

Formwork installation process for installing the formwork on the formwork support;

A slab construction process of installing a slab using the formwork;

When the slab hypothesis is completed in the above process, the demolition process consists of removing the jack, the cross beam, the jack support device and the formwork support.

Girder bridge slab installation method of the present invention made as described above, can be used in all types of girder bridge bar H-shaped steel in place of the formwork support bracket for slab casting in the girder bridge to support the slab with a support beam of a certain form In addition, it is possible to install the 'c' shaped steel in the axial direction of the bridge to support the die.

That is, the PC beam bridge 500 is provided with formwork support 130 on both sides of the support beam 510, as shown in Figure 15a and 15b, the cross beam 120 is located at the bottom of the formwork support 130 Hydraulic jack 110 is installed at the bottom of the crossbeam to support the crossbeam 120, the hydraulic jack 110 is located above the prefabricated jack support device 300, the prefabricated jack support device 300 It is fixed to the bridge and concentrates the weight of the formwork support 130 and the slab 530 to the piers.

Here, the cross beam 120, the hydraulic jack 110, and the assembled jack support device 300 may be installed at the lower end of the support beam 510 as shown in FIG. 15A, and may be installed between the support beam 510 as shown in FIG. 15C. It may be.

As shown in FIG. 16, the plate-shaped bridge 400, which is a type of girder bridge, is provided with formwork supports 130 on both sides of the steel plate 410, which is manufactured to support the slab 430, and the formwork support ( A cross beam 120 is positioned and supported at a lower end of the 130, and a hydraulic jack 110 is installed at a lower end of the cross beam 120 to support the cross beam 120, and the hydraulic jack 110 is a prefabricated jack support device ( Located at the top 300, the prefabricated jack support device 300 is fixedly supported on the bridge to concentrate the weight of the formwork support 130 and the slab 430 to the piers.

In addition, as shown in FIG. 17, the steel box bridge 600, which is another type of girder bridge, is provided with formwork supports 130 on both sides of the steel box 620 manufactured to support the slab 630. A cross beam 120 is positioned and supported at the bottom of the form support 130, and a hydraulic jack 110 is installed at the bottom of the cross beam 120 to support the cross beam 120, and the hydraulic jack 110 is a prefabricated jack. Located on the upper portion of the support device 300, the prefabricated jack support device 300 is fixed to the bridge to concentrate the weight of the formwork support 130 and the slab 630 to the piers.

The configuration of the prefabricated jack support device used in the girder bridge installation process is the same as the configuration of the prefabricated bracket used for the slab bridge.

As a result, the present invention can omit the conventional bracket installation step in the girder bridge installation step, and instead install the formwork support 130 on the prefabricated jack support device 300 and the lifting hydraulic jack 110 instead. It is possible, thereby eliminating the inconvenience of having to install all the brackets at regular intervals, it is possible to shorten the air and more fully ensure the safety of the operator.

In addition, even in the process of demolition, in order to remove the brackets installed between the support beams in the prior art, the worker must work at risk, but the demolition work is carried out using heavy equipment. It is possible to work, and at the same time, it can have side effects that can prevent the accident of workers.

Therefore, when using the present invention, in installing the slab of the slab bridge, ramen bridge and girder bridge, slab casting without using the existing copper bar at all because it supports the formwork installation process as a prefabricated support device, impression jack and formwork support means. The construction of the bridge makes it very easy to build bridges and is very advantageous in demolition work.

Claims (9)

A piers and shift construction process for constructing bridges and shifts at regular intervals in the space where a bridge is to be constructed; A prefabricated jack support installation process of installing a prefabricated jack support device for raising on the pier and the shift; A mold support installation step of placing the jack and the cross beam on the support plate body of the assembled jack support device and installing the form support on the upper portion thereof; Formwork installation process for installing the formwork on the formwork support; A slab construction process of installing a slab using the formwork; The slab installation method of the slab bridge using the prefabricated support device characterized in that when the slab hypothesis is completed in the process comprises a demolition process of removing the jack and the cross beam and the prefabricated jack support device and the formwork support. A piers and shift construction process for constructing bridges and shifts at regular intervals in the space where a bridge is to be constructed; A bridge beam installation step of axially installing prefabricated bridge beams in the bridges and bridges; A prefabricated jack support device installation process of installing a prefabricated jack support device for the impression on the pier and the shift; Placing the jack and the cross beam on the support plate body of the prefabricated jack support device, and installing the formwork support on the upper portion, and installing the formwork support having the same height as the beam between the bridge beams; Formwork installation process for installing the formwork on the formwork support; A slab construction process of installing a slab using the formwork; The slab installation method of the girder bridge using the prefabricated support device, characterized in that the slab construction is completed when the jack and the cross beam and the prefabricated jack support device and the formwork support to demolish. An anchor and pier and alternating process for constructing bridges and shifts at regular intervals in the space for constructing bridges, while laying the anchors; A prefabricated jack support device installation process of fixing a vertical connecting plate to the anchor bar and installing a support piece and a reinforcing beam on the vertical connecting plate; A mold support installation step of placing a jack and a cross beam on the support plate body of the assembled jack support device, and installing a form support on the upper portion thereof; Formwork installation process for installing the formwork on the formwork support; A slab construction process of installing a slab using the formwork; When the slab hypothesis is completed in the above step, the slab installation method of the ramen bridge using a prefabricated support device, characterized in that the demolition process of removing the jack and the cross beam and the prefabricated jack support device and formwork support. The method according to claim 1 or 2, Mounting and assembling one side and the other base plate around each bridge device located on the top of the bridge and installing the support device in the axial direction of the bridge, and facing the jack on the support plate of each of the supporting hardware on both sides of the support device The slab installation method using a prefabricated support device, characterized in that for holding the formwork by holding the formwork by placing the jacks to raise the impression. The method of claim 1, The prefabricated support device is a slab bridge slab installation method using a prefabricated support device, characterized in that the assembly in front and rear after being fixed in the bridge axially divided into two upper portions. The method of claim 2, The prefabricated support device is any one of the two divided in the axial direction of the bridge, or divided into two in the direction perpendicular to the bridge axis, and after fixing the prefabricated support device on the top of the bridge, characterized in that it is assembled at the front and rear or intermediate points Girder bridge slab installation method using a prefabricated support device. The method according to claim 1 or 2, In the dismantling process, after removing the supporting plate body of the prefabricated jack support device, the tension jack is installed on the upper part of the slab, and the form support is connected by wire through a drain hole that is prefabricated in the slab, and the form support is lowered to a certain length. Method for dismantling the prefabricated support device, characterized in that it further comprises a step of utilizing the slab construction status and the workbench at work. The method according to claim 1 or 2, Wherein the formwork support is a slab installation method using a prefabricated support device, characterized in that any one selected from the support structure, including H-shaped steel or '' '. The method of claim 3, wherein The supporting device is composed of a vertical connecting plate, a bracing piece and a reinforcing beam, and when the installation of the prefabricated jack supporting device is completed as described above, a formwork support is installed thereon, and a slab is placed on the formwork support. Slave installation method of the ramen bridge using the prefabricated support device characterized in that.