KR102612270B1 - Prevention apparatus for turnover of girder for remote construction - Google Patents

Abstract

The present invention relates to a fall prevention device for a girder for remote construction installed on a girder of a bridge for remote construction, which includes a support part installed on both sides of the girder, and a support part installed on top of the support part to fix the support part to both sides of the girder. It is characterized by comprising a fixing part for coupling, and a thrust part installed at the lower part of the support part to provide elastic force to the support part based on the support block of the bridge pier. Therefore, the present invention installs the fall prevention device of the support portion and the impact portion on the sides of both ends of the girder by a fixed part and maintains it in a permanent or detachable manner, thereby minimizing the deployment of manpower for attaching and detaching the fall prevention device, thereby reducing costs. It provides the effect of shortening the construction period.

Description

Falling prevention device for girders for remote construction {PREVENTION APPARATUS FOR TURNOVER OF GIRDER FOR REMOTE CONSTRUCTION}

The present invention relates to a device for preventing girders for remote construction from falling, and more specifically, to a device for preventing girders for remote construction installed on girders of bridges for remote construction.

When installing facilities at a construction or civil engineering site, members such as I-beams, T-beams, or girders are mainly used. These members are manufactured by methods such as precast near the site and transported to the site. .

It is common to place multiple of these members in parallel in a yard on the ground when mounting or manufacturing them, and when an unexpected external force is applied to a member, multiple members placed in parallel tip over continuously, causing serious casualties and material damage due to a large-scale accident. Damage, etc. occurs.

These problems are because a flange, which is a protruding shape, is formed around the circumference of the member. Even if a flange is formed, it can be relatively easily balanced when in a stationary state, but when an unexpected external force is applied, the flange is affected by the external force. Due to the applied load, conduction occurs easily.

Moreover, in the field, such overturning problems occur more easily because the member is simply supported by its own weight according to the structure of the member due to the lack of supports to secure the member during storage, storage, or transportation.

Ultimately, many fall prevention devices have been developed to solve this problem of fall, but there is no fall prevention device that prevents fall in all cases of storing, storing, and transporting members.

In particular, the fall prevention stop of a conventional girder is generally made of a prestressed concrete beam (PSC-BEAM) or an eye (I) type girder made of a free flex beam (FREFLEX BEAM), and the upper and lower flanges ( A member composed of an I-shaped structure consisting of a FLANGE and a web of the vertical part is mounted on the pier coping at the top of the pier.

In this conventional technology, a bridge support block is formed on the top of the pier coping, and the girder is supported on the bridge support block. In order to prevent the collapse of the girder under work, wire ropes and fixed anchors are connected and fixed to prevent the girder from flowing. It prevents collapse.

However, these conventional fall prevention devices have the risk of falling due to natural or artificial conditions, so it is necessary to improve the stability of the construction, and there is a problem that constructability must be improved by simplifying the installation of the installed fall prevention device. there is.

In addition, the conventional structure for preventing the girder from falling is to install a turn buckle on the coping, connect a strand to it, and support the upper flange with the strand to prevent the girder from falling.

However, since this conventional girder fall prevention device is a temporary structure required during construction, it should be easy to install and dismantle. However, because of the manpower work for installation and dismantling on the upper part of the pier, it is necessary to place workers on the bridge surface for installation and dismantling. There was a problem that it became inevitable and the risk of safety accidents increased due to this.

In addition, the conventional technology had a problem in that the girder fall prevention device could be damaged by drilling a girder support structure (coping or pier) and then separately installing a turnbuckle for installation.

Republic of Korea Patent No. 10-0632816 (October 11, 2006) Republic of Korea Patent No. 10-0724596 (June 4, 2007) Republic of Korea Patent No. 10-1480789 (January 14, 2015)

The present invention was devised to solve the above-mentioned problems, and the fall prevention device is installed on both ends of the girder by means of a fixed portion and maintained in a permanent or detachable manner. The purpose is to provide a fall prevention device for girders for remote construction that can reduce costs and shorten the construction period by minimizing the deployment of manpower for attachment and detachment.

In addition, the present invention installs the fall prevention device to be detachable by a fixing part and maintains it permanently, thereby minimizing the placement of workers on the abutment surface of a bridge pier with a narrow work space and installation space and preventing safety accidents in advance. Another purpose is to provide a device to prevent girders from falling over for remote construction.

In addition, the present invention is provided with a first support piece and a second support piece as a support portion, so that the conduction force caused by the swing when the girder is mounted is separated into the vertical and horizontal directions, thereby improving the fall prevention force and the support rigidity of the support portion. Another purpose is to provide a fall prevention device for girders for remote construction that can improve.

In addition, the present invention provides a third support piece and a fourth support piece as a support portion, thereby preventing the first support piece from falling by separately supporting the conductive force caused by the rocking motion when the girder is mounted on the upper and lower ends of the inclined first support piece. Another purpose is to provide a fall prevention device for a girder for remote construction that can improve the strength and the support rigidity of the first support piece at the same time.

In addition, the present invention provides a first fixing piece and a second support piece as a fixing part, or is provided to be detachable with a fitting or a locking part, thereby maintaining a strong fixed coupling force between the girder and the support part and at the same time maintaining it to be detachable so that it remains permanently. Another purpose is to provide a fall prevention device for girders for remote construction that can be easily applied in a detachable and attachable manner.

In addition, the present invention is provided with a coil spring that resists the vertical conduction force when the girder falls at the bottom of the support portion as a resilient portion, thereby providing a resilient force to prevent the girder from falling without damage to the abutment surface of the pier or separate installation work. Another purpose is to provide a fall prevention device for remote construction girders that can maintain.

The present invention for achieving the above object is a girder fall prevention device installed on a bridge girder for remote construction, including support parts 10 installed on both sides of the girder; A fixing part 20 installed on the upper part of the support part 10 to fixedly couple the support part 10 to both sides of the girder; And a thrust portion 30 installed at the lower part of the support portion 10 to provide a resilient force to the support portion 10 based on the support block of the bridge pier.

The support portion 10 of the present invention includes first support pieces installed on both sides of the girder to support horizontal conduction force when the girder falls; and a second support piece installed below the first support piece to support vertical conduction force when the girder falls.

The support part 10 includes a third support piece installed on an upper end of the first support piece and supporting the upper end of the first support piece. and a fourth support piece installed at a lower end of the first support piece to support the lower end of the first support piece.

The fixing part 20 of the present invention includes a first fixing piece installed embedded in both sides of a girder and having fixing holes to which fastening fixing members are coupled; And a second fixing piece installed on the support part 10, coupled and fixed to the first fixing piece, and having a coupling hole through which a fastening fixing member is coupled.

The fixing part 20 of the present invention is characterized by being composed of a fitting piece or a locking piece installed on both sides of the support part 10 and the girder to correspond to each other.

The elastic portion 30 of the present invention is characterized in that it is composed of a coil spring installed at the lower part of the support portion 10 to resist the conductive force in the vertical direction when the girder falls.

As discussed above, the present invention minimizes the deployment of manpower for attachment and detachment of the fall prevention device by installing the fall prevention device of the support portion and the ridge portion on both ends of the girder by a fixed part and maintaining it in a permanent or detachable manner. This provides the effect of reducing costs and shortening the construction period.

In addition, by installing the fall prevention device to be detachable by a fixing part and maintaining it permanently, the arrangement of workers on the abutment surface of a bridge pier with a narrow work space and installation space can be minimized and safety accidents can be prevented in advance. provides.

In addition, by providing a first support piece and a second support piece as a support portion, the conduction force caused by the swing when mounting the girder is supported separately in the vertical and horizontal directions, thereby improving the fall prevention force and at the same time improving the support rigidity of the support portion. Provides an effect that can be achieved.

In addition, by providing a third support piece and a fourth support piece as the support portion, the conduction force caused by the shaking when the girder is mounted is supported separately at the upper and lower ends of the inclined first support piece, thereby improving the fall prevention ability of the first support piece. At the same time, it provides the effect of improving the support rigidity of the first support piece.

In addition, by providing a first fixing piece and a second support piece as a fixing part, or providing a detachable attachment or stopping piece, the fixed coupling force between the girder and the support part is maintained strongly and at the same time, it is maintained to be detachable, so that it can be permanently attached and detachable. It provides an effect that can be easily applied in this way.

In addition, by providing a coil spring at the bottom of the support portion as a resilient portion to resist the vertical conductive force when the girder falls, it is possible to maintain the elastic force to prevent the girder from falling without damaging the pier's bearing surface or performing separate installation work. Provides effective effects.

Figure 1 is a configuration diagram showing a device for preventing fall of a girder for remote construction according to a first embodiment of the present invention.
Figure 2 is a top view showing a device for preventing fall of a girder for remote construction according to the first embodiment of the present invention.
Figure 3 is a front view showing the construction state of the device for preventing fall of a girder for remote construction according to the first embodiment of the present invention.
Figure 4 is a side view showing the construction state of the device for preventing fall of a girder for remote construction according to the first embodiment of the present invention.
Figure 5 is a state diagram showing the construction state of the device for preventing fall of a girder for remote construction according to the first embodiment of the present invention.
Figure 6 is a state diagram showing the installation state of the fall prevention device for a girder for remote construction according to the first embodiment of the present invention.
Figure 7 is a front view showing the construction state of the device for preventing fall of a girder for remote construction according to the second embodiment of the present invention.
Figure 8 is a side view showing the construction state of the device for preventing fall of a girder for remote construction according to the second embodiment of the present invention.
Figure 9 is a state diagram showing the installation state of the device for preventing fall of a girder for remote construction according to the second embodiment of the present invention.

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

Figure 1 is a configuration diagram showing a device for preventing fall of a girder for remote construction according to a first embodiment of the present invention, and Figure 2 is a top view showing a device for preventing a fall of a girder for remote construction according to a first embodiment of the present invention. 3 is a front view showing the construction state of the device for preventing fall of girders for remote construction according to the first embodiment of the present invention, and Figure 4 is the device for preventing fall of girders for remote construction according to the first embodiment of the present invention. It is a side view showing the construction state, Figure 5 is a state diagram showing the construction state of the fall prevention device for remote construction girder according to the first embodiment of the present invention, and Figure 6 is a remote construction state according to the first embodiment of the present invention. It is a state diagram showing the installation state of the fall prevention device of the common girder, Figure 7 is a front view showing the construction state of the fall prevention device of the girder for remote construction according to the second embodiment of the present invention, and Figure 8 is the second embodiment of the present invention. It is a side view showing the construction state of the fall prevention device for girders for remote construction according to the embodiment, and Figure 9 is a state diagram showing the installation state of the device for preventing fall of girders for remote construction according to the second embodiment of the present invention.

Hereinafter, a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 to 4, the device for preventing the fall of a girder for remote construction according to the first embodiment includes a support part 10, a fixing part 20, and a retaining part 30, and is used to prevent the fall of a girder for bridge girder. (100) It is a fall prevention device for various PSC (Prestressed Concrete) girders installed for remote construction.

The support portion 10 is a support member that is installed symmetrically on both sides of the girder 100, and is made of precast concrete or steel at the end of the girder with a fall prevention wing member that is factory-fabricated or manufactured on-site. It is combined and consists of a first support piece (11) and a second support piece (12).

In this way, the permanent type in which the support part 10 is made of precast concrete does not require manpower for dismantling work on the seating surface, but it is of course possible that manpower work is required when recovering after manufacturing steel.

The first support piece 11 is a support member installed at an angle on both sides of the girder 100 so that its lower ends are spaced apart to support the horizontal conductive force when the girder 100 falls, and is a pillar member formed in a roughly triangular shape. It is made up of a triangular shape to support the transverse horizontal force when the girder 100 falls.

The second support piece 12 is a support member that is formed to protrude from the lower end of the first support piece 11 and supports the conductive force in the vertical direction when the girder 100 falls. This second support piece 12 consists of a protruding member protruding from the lower outer end of the first support piece 11 to support the conductive force of the girder 100.

The fixing part 20 is a fixing member installed on the upper part of the support part 10 to fixedly couple the support part 10 to both sides of the girder 100, and includes the first fixing piece 21 and the second fixing piece 22. ) consists of.

The first fixing piece 21 is a fixing member that is embedded and installed on both sides of the girder 100 during pouring and has fixing holes through which fastening fixing members are coupled. The fixing holes are formed in a plurality of fixing holes symmetrically in the up-down and left-right directions. It is formed to maintain the bonding strength and fixed bearing capacity even when the girder 100 is tilted left and right or tilted up and down.

The second fixing piece 22 is a fixing member that is embedded and installed in the support portion 10 during pouring, is fixed to the first fixing piece 21, and has a coupling hole through which the fastening fixing member is coupled. The coupling hole is located in the vertical direction. And a plurality of girders are formed symmetrically in the left and right directions to maintain bonding strength and fixed bearing capacity even when the girder 100 is tilted left and right or tilted up and down.

In addition, this fixing part 20 is composed of a fitting piece or a locking piece installed on both sides of the support part 10 and the girder 100 to correspond to each other, and is installed in a temporary automatic detachable manner during remote construction, so that it can be installed by automatic screws, etc. Of course, it is also possible to easily attach or detach the support portion 10 from the girder 100 remotely.

The resilient portion 30 is fixedly installed at the lower part of the support portion 10 and provides a resilient force to the girder 100 and the support portion 10 that rock when falling with respect to the support block 210 of the bridge pier 200. As a resilient member, it is inserted and installed between the upper surface of the bridge pier 200 and the second support piece 12 of the support portion 10 to provide resilient force.

This elastic portion 30 is fixedly coupled to the lower part of the second support piece 12 of the support portion 10 via a fixing member and consists of a coil spring that resists the conductive force in the vertical direction when the girder 100 falls. Of course, this is also possible.

As shown in (a), (b), (c), (d), and (e) of FIGS. 5 and 6, the fall prevention device of the present invention is installed on the support block 210 of the adjacent pier 200. In order to mount both ends of the girder 100, the support portion 10 and the impact portion 30 are sequentially coupled and fixed to the side portions of both ends of the girder 100 by the fixing portion 20, respectively. Overturning due to the shaking of the city girder 100 is prevented.

Hereinafter, a second embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 7 to 9, the fall prevention device for a girder for remote construction according to the second embodiment includes a support part 10, a fixing part 20, and a retaining part 30, and is used to prevent the fall of a girder for bridge girder. (100) It is a fall prevention device for various PSC (Prestressed Concrete) girders installed for remote construction.

The fixing part 20 and the impact part 30 of the second embodiment are the same as those of the first embodiment, so the same reference numerals are given and detailed description is omitted, and only the support part 10, which has a different configuration from the first embodiment, is described in detail. It is explained as follows.

The support portion 10 is a support member that is installed symmetrically on both sides of the girder 100, and is made of precast concrete or steel at the end of the girder with a fall prevention wing member that is factory-fabricated or manufactured on-site. It is combined and consists of a first support piece (11), a second support piece (12), a third support piece (13), and a fourth support piece (14).

In this way, the permanent type in which the support part 10 is made of precast concrete does not require manpower for dismantling work on the seating surface, but it is of course possible that manpower work is required when recovering after manufacturing steel.

The first support piece 11 is a support member installed at an angle on both sides of the girder 100 so that its lower ends are spaced apart to support the horizontal conductive force when the girder 100 falls, and is a pillar member formed in a roughly triangular shape. It is made up of a triangular shape to support the transverse horizontal force when the girder 100 falls.

The second support piece 12 is a support member that is formed to protrude from the lower end of the first support piece 11 and supports the conductive force in the vertical direction when the girder 100 falls. This second support piece 12 consists of a protruding member protruding from the lower outer end of the first support piece 11 to support the conductive force of the girder 100.

The third support piece 13 is a support member installed on the upper end of the first support piece 11 to fix and support the upper end of the first support piece 11, and is coupled on one side to the fixing portion 20. The other side is coupled to the first support piece 11 to support the first support portion 11 by being fixedly coupled to the fixing portion 20.

The fourth support piece 14 is a support member installed on the side of the first support piece 11 to support the lower end of the first support piece 11 in a spaced apart state, and has one side at the bottom of the girder 100. The other side is coupled to the lower end of the first support piece 11 to support the lower end of the first support part 11 at a predetermined distance from the lower end of the girder 100.

As shown in Figures 9 (a), (b), and (c), the fall prevention device of the present invention is a girder so that both ends of the girder 100 are mounted on the support block 210 of the adjacent pier 200. The support portion 10 and the impact portion 30 are sequentially coupled and fixed to the side portions of both ends of the girder 100 by the fixing portion 20 to prevent conduction due to the shaking of the girder 100 when the girder 100 is mounted. It is prevented.

As explained above, according to the present invention, the fall prevention device of the support portion and the ridge portion is installed on the sides of both ends of the girder by a fixed part and maintained in a permanent or detachable manner, thereby minimizing the deployment of manpower for attachment and detachment of the fall prevention device. This provides the effect of reducing costs and shortening the construction period.

In addition, by installing the fall prevention device to be detachable by a fixing part and maintaining it permanently, the arrangement of workers on the abutment surface of a bridge pier with a narrow work space and installation space can be minimized and safety accidents can be prevented in advance. provides.

In addition, by providing a first support piece and a second support piece as a support portion, the conduction force caused by the swing when mounting the girder is supported separately in the vertical and horizontal directions, thereby improving the fall prevention force and at the same time improving the support rigidity of the support portion. Provides an effect that can be achieved.

In addition, by providing a first fixing piece and a second support piece as a fixing part, or providing a detachable attachment or stopping piece, the fixed coupling force between the girder and the support part is maintained strongly and at the same time, it is maintained to be detachable, so that it can be permanently attached and detachable. It provides an effect that can be easily applied in this way.

In addition, by providing a coil spring at the bottom of the support portion as a resilient portion to resist the vertical conductive force when the girder falls, it is possible to maintain the elastic force to prevent the girder from falling without damaging the pier's bearing surface or performing separate installation work. Provides effective effects.

The present invention described above can be implemented in various other forms without departing from its technical idea or main features. Therefore, the above embodiment is merely an example in all respects and should not be construed as limited.

10: support part
20: Fixing part
30: Tanjibu

Claims (6)

As a girder fall prevention device installed on a bridge girder for remote construction,
Support parts 10 installed on both sides of the girder;
A fixing part 20 installed on the upper part of the support part 10 to fixedly couple the support part 10 to both sides of the girder; and
It includes a resilient portion (30) installed at the lower part of the support portion (10) and providing a resilient force to the support portion (10) based on the support block of the bridge pier,
The support portion 10,
First support pieces installed on both sides of the girder to support horizontal conduction force when the girder falls;
a second support piece installed below the first support piece to support vertical conduction force when the girder falls;
a third support piece installed on an upper end of the first support piece and supporting the upper end of the first support piece; and
A fourth support piece is installed horizontally on the side of the first support piece and supports the lower end of the first support piece at a distance from both sides of the girder,
The fixing part 20 is composed of a fitting piece or a locking piece installed on both sides of the third support piece of the support portion 10 and the girder 100 to correspond to each other, A first fixing piece 21 is embedded and installed on both sides when pouring and has a fixing hole into which a fastening fixing member is coupled, and is embedded and installed on the support part 10 when pouring and is coupled to the first fixing piece 21. It consists of a second fixing piece (22) formed with a coupling hole into which the fastening fixing member is fixed,
It is installed in a temporary automatic detachable manner during remote construction, and is characterized in that the support part 10 is easily attached or separated from the girder 100 remotely by automatic screws on the first fixing piece and the second fixing piece. A device to prevent girders from falling over for remote construction. delete delete delete delete According to claim 1,
The elastic portion (30) is a device for preventing fall of a girder for remote construction, characterized in that it is installed at the lower part of the support portion (10) and consists of a coil spring that resists the conduction force in the vertical direction when the girder falls.

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