KR102170886B1 - Building repair method - Google Patents

Abstract

The present invention relates to a rapid and smart method of lifting a structure, which uses an apparatus for correcting cracks and abnormal displacement of the structure generated by aging of the structure or constant natural disasters so as to remove the ground around the structure with the abnormal displacement, select a position by considering the leaning direction of the structure and the position of cracks, and bury a lathe connection pipe and a plurality of connection pipes by a hydraulic pressure through a rotary cylinder at the selected position of the structure. When the front end connection pipe is buried down to a firm ground layer, the structure is supported by a beam, and a hydraulic apparatus is installed on an upper surface of the connection pipe engaged with a connection pipe mounting plate to be operated so as to lift the structure by raising the beam along a bracket formed on one side of the beam. At the same time, the cracks of the structure are matched. In addition, the present invention is able to frequently check the displacement of a building through a vibration detection sensor and at the same time, automatically block electricity in the structure when a natural disaster occurs, thereby preventing accidents.

Description

Fast and smart structure raising method {Building repair method}

The present invention is an apparatus for correcting cracks and abnormal displacements of structures caused by aging of structures or subsequent natural disasters,

After removing the ground around the structure where the abnormal displacement has occurred, the position is selected in consideration of the inclined direction of the structure and the location of the crack, and the end connector and a plurality of connecting tubes through a rotary continuous cylinder at the selected structure location To be buried hydraulically.

When the end connector is buried to a solid ground layer, the structure is supported through a girder, and a hydraulic device is installed on the upper surface of the connector coupled to the connector mounting plate to operate, so that the girder rises along the bracket formed on one side of the girder. Lift the structure and at the same time allow it to hit the cracks in the structure.

In addition, it relates to a rapid and smart structure lifting method device, characterized in that it is possible to prevent safety accidents by automatically shutting off power in the structure when a natural disaster occurs while at the same time checking the displacement of a building through a vibration sensor.

In general, in order to construct various buildings or structures, the work of reinforcing the ground must be performed first so that the structure or structure is not damaged or collapsed due to subsidence of the ground.

If the stratum conditions in contact with the structure are satisfactory and sufficient support is secured, foundation work can be performed directly on the ground-bearing foundation, but in the case of stratum conditions that are not, piles are constructed to secure support and prevent ground subsidence. . The piles used at this time are classified into steel pipe piles, PHC piles, etc. according to their material, and pipe-shaped piles are generally used.

However, there is no way to quickly and simply solve the cracks of structures due to natural disasters such as earthquakes or structures that have not performed the foundation work or old buildings.

Therefore, the present invention raises the cracked structure to match the crack, maintains it continuously, and interlocks with the inside of the structure to automatically cut off the electricity supply when a natural disaster such as an earthquake occurs. We would like to suggest a smart construction method that can achieve reinforcement at the same time.

Republic of Korea Patent Registration 10-1470796 (Registration date December 2, 2014)

To solve the above problems,

After removing the ground around the structure where the abnormal displacement has occurred, the position is selected in consideration of the inclined direction of the structure and the location of the crack, and the tip connector and a number of connectors are hydraulically operated at the selected structure location through a rotary cylinder. Buried with,

When the end connection pipe is buried to a solid ground layer, the structure is supported through the girder, and a hydraulic device is installed on the upper surface of the connection pipe coupled to the connection pipe mounting plate to operate, so that a girder is constructed, but the girder is formed along the bracket formed on one side. To lift the structure and at the same time hit the cracks in the structure,

The purpose of the invention is to provide a quick and smart structure lifting method characterized in that it is possible to prevent safety accidents by automatically shutting down power in the structure when a natural disaster occurs while at the same time checking the displacement of a building through a vibration sensor. do.

The present invention to achieve the above object,

Identifying the crack location of the structure where the crack has occurred, and excavating so that the bottom surface of the structure at the identified crack location is exposed to the outside (S10),

After installing a rotary continuous cylinder in which a plurality of loading holes are formed along the outer circumference at a predetermined interval from the exposed bottom surface,

In the mounting hole configured inside the loading hole, the front end connector and a plurality of connector are loaded, and the cylinder constituting the rotary continuous cylinder and the hydraulic device located on the upper side thereof are on the same line as the mounting hole in which the end connector is loaded. Position it, then

The step (S20) of first burying the tip connector pipe in the ground through a hydraulic device, but penetrating through a guideline formed on one lower side of the cylinder constituting a rotary continuous cylinder,

It has a diameter smaller than the upper surface of the buried end connector, but is buried until it is buried in a solid ground layer by forming a plurality of connecting pipes formed at the lower end of the connecting protrusion protruding so as to be coupled to the upper surface of the end connector. , The final buried connection pipe is buried using a threaded connection pipe 13B having a screw wire formed on the upper outer circumferential surface (S30),

After the burial is completed through the step S30, the rotary continuous cylinder is removed, and the bottom surface of the structure is supported by an L-shaped pedestal formed on one side of the girder, and one side of the connecting pipe mounting plate configured on the other side of the girder The step (S40) of coupling with the connector through the slide hole formed in the,

After connecting the hydraulic device with a pair of brackets penetrating the pair of first holes formed on the left and right sides of the connecting pipe mounting plate of the girder, the bracket is hydraulically raised to simultaneously lift the structure supported by the girder to prevent cracking. And matching step (S50),

After supporting the connection pipe mounting plate by tightening the nut fastened to the upper end of the threaded connection pipe, a pair of second holes are formed on both left and right sides, and a fixing cap having a mounting protrusion in the center of the bottom surface constitutes the girder. A pair of brackets formed on one side of the connecting pipe mounting plate and the connecting pipe mounting plate are fixed by penetrating and connecting to the upper surface of the connecting pipe coupled to the connecting pipe mounting plate, and fastening the bolts formed at the upper and lower ends of the bracket. It characterized in that it comprises a step (S60) to firmly support the structure in which the cracked structure does not crack again by forming a solid coupling between the tip connector, the connector, and the girder buried in the hard ground layer while the cap is solidly coupled. It provides a quick and smart structure impression method.

The present invention has the following effects.

The present invention has the effect of reinforcing a structure in which cracks have occurred by raising a structure, and preventing cracks from occurring again by continuously supporting the structure even after reinforcement.

In addition, the vibration detection sensor detects an earthquake, and it is interlocked with the interior of the structure to automatically cut off the electricity supply when the earthquake is detected, thereby preventing safety accidents.

1 is a view showing excavation so that the bottom surface of the structure is visible according to the quick and smart structure impression method.
Figure 2 is a view showing that the front end connector and the connector are buried in the ground through a rotary continuous cylinder according to the smart structure raising method, and are fixed to a solid ground layer.
Figure 3 is a view showing the removal of the rotary continuous cylinder and installing a crossbeam according to a smart structure raising method.
Figure 4 is a view showing raising the girder according to the smart structure raising method.
Fig. 5 is a view showing that the hydraulic jack is removed and the fixing cap is mounted on the upper surface of the connector to securely fix the structure.
Figure 6 is an exemplary view coupled to the rotary continuous cylinder according to the smart structure impression method.
Figure 7 is a combination of a rotary continuous cylinder according to the smart structure impression method.
8 is a view showing that the connection pipe is fixed through the connection pipe fixing pin of the rotary continuous cylinder according to the smart structure raising method.
9 is a view showing an exemplary side view of a rotary continuous cylinder according to a smart structure raising method and a front end connector installed with an earthquake detection sensor.
10 is an exploded perspective view of a girder according to a smart structure impression method.
11 is a perspective view of a girder combination according to a smart structure impression method.
12 is a view showing the bottom surface of the cap according to the smart structure impression method.

Hereinafter, specific contents will be described together with the drawings.

1 to 11,

Identifying the crack location of the structure where the crack has occurred, and excavating so that the bottom surface of the structure at the identified crack location is exposed to the outside (S10),

After installing the rotary continuous cylinder 1 in which a plurality of loading holes 11 are formed along the outer circumference at a predetermined interval from the exposed bottom surface,

The front end connector 12 and a plurality of connector 13 are loaded in the mounting hole 11A configured inside the loading hole 11, but the cylinder 10 constituting the rotary continuous cylinder 1 and the upper side thereof The hydraulic device 16 located in is positioned on the same line as the mounting hole 11A in which the tip connector 12 is loaded,

The step of first burying the tip connector 12 in the ground through the hydraulic device 16, but penetrating through the guideline 22 formed at the lower side of the cylinder 10 constituting the rotary continuous cylinder 1 (S20) Wow,

A plurality of connection pipes 13 formed at the bottom of which a coupling protrusion 13A protruding so as to be coupled to the upper surface of the buried tip connector 12 is formed in a smaller diameter than the upper surface Buried until the bonding is made and buried in a solid ground layer, but the final buried connector 13 is buried using a threaded connector 13B having a screw thread formed on the upper outer peripheral surface (S30),

After the burial is completed through the step S30, the rotary continuous cylinder 1 is removed, the L-shaped pedestal 30 formed on one side of the girder 2 supports the bottom surface of the structure, and the girder 2 ) A step (S40) of coupling with the connection pipe 13 through the slide hole 41 formed on one side of the connection pipe mounting plate 40 configured on the other side,

After connecting the hydraulic device 16 with a pair of brackets 43 penetrating the pair of first holes 42 formed on the left and right sides of the connecting pipe mounting plate 40 of the girder 2, the bracket 43 ) By hydraulically lifting the structure supported by the girder (2) and fitting the crack by simultaneously lifting (S50),

After supporting the connector mounting plate 40 by tightening the L-shaped plate fixing nut 13C fastened to the upper end of the threaded connector 13B, a pair of second holes 51 are formed on both left and right sides, A pair of brackets 43 formed on one side of the connecting pipe mounting plate 40 constituting the girder 2 and the connecting pipe mounting plate 40 with a fixing cap 50 having a mounting protrusion groove 52 formed in the center of the surface The connection pipe 13 coupled to the upper surface of the connection pipe 13 is penetrated and coupled, and the connection pipe mounting plate 40 and the fixing cap 50 to which the connection pipe 13 is coupled by tightening the bolts formed at the upper and lower ends of the bracket 43 A step in which the front end connector 12, the connector 13, and the girder 2 embedded in the hard ground layer are firmly bonded to form a solid bond so that the structure hitting the crack is firmly supported so that no crack occurs again (S60) Includes.

Hereinafter, specific contents will be described together with the drawings.

[Excavation step S10]

As shown in Fig. 1, after determining the location of the crack of the structure where the structure is old or cracked due to an earthquake, excavation is performed so that the bottom surface of the structure is exposed to the outside.

[Step S20 for laying the end connector after installing the rotary continuous cylinder]

After excavating so that the bottom of the structure is visible,

As shown in Fig. 2, a rotary continuous cylinder 1 is installed in the ground just below the excavated structure floor.

In addition, the rotary continuous cylinder 1 has 5 to 15 loading holes 11 formed along the outer circumference.

In addition, a mounting hole 11A capable of mounting the end connector 12 and the plurality of connector 13 is formed inside the loading hole 11, and the end connector 12 is formed in the mounting hole 11A. ) And a plurality of connecting pipes 13 are mounted.

The hydraulic device 16 formed on the upper side of the cylinder 10 constituting the rotary continuous cylinder 1 is positioned on the same line as the loading hole 11 in which the tip connector 12 is loaded.

The case 20 constituting the rotary continuous cylinder 1 mounts the cylinder 10, and one side of the case 20 allows the front end connector 12 and the connector 13 to enter the ground. An open inlet 21 is formed.

In addition, it is preferable that the front end connector 12 is first buried in the ground through the hydraulic device 16.

At this time, the tip connector 12 is buried through a guide line 22 formed at the bottom of the cylinder 10 constituting the rotary continuous cylinder 1.

Since it is buried through the guide line 22, it is possible to enter in a vertical direction without deviating from the path when buried up to the hard ground layer.

In addition, the tip connector 13 is formed in a tip shape so as to penetrate the ground at the bottom. The tip connector 13 has a tip shape to reduce friction with the ground so that it can easily reach a hard ground layer.

In addition, as shown in Fig. 11, the front end connector 12 has an earthquake detection sensor 12A formed at the inner center. The earthquake detection sensor 12A can be connected to the inside of the structure in a WIFI manner and the network is interlocked to prevent a safety accident while forcibly shutting off power when an earthquake occurs.

The vibration detection sensor 12A is equipped with an acceleration sensor and a gyro sensor to measure vibration and inclination values in real time, and measure the acceleration and inclination values to compare and measure the current state with the installation point. It sends a signal to the inside of the connected structure.

More specifically, the output signal is processed through the acceleration sensor to predict the acceleration, vibration, and impact of the object, and the inclination is measured through the gyro sensor, and the current state is compared with the installation point and measured. It sends a signal to the inside of the connected structure.

In addition, the upper surface of the front end connector 12 is coupled with a coupling protrusion 13A protruding from the lower end of the connector 13.

[Step S30 of repeating the tip connector and the connector through the hydraulic burial device until buried in the solid ground layer]

As shown in Fig. 3, after the front end connector 12 loaded in the mounting hole 11A inside the loading hole 11 is first buried in the ground through the hydraulic device 16,

The upper surface of the front end connector 12 is coupled with a coupling protrusion 13A protruding from the lower end of the connector 13.

The connection pipe 13 has a protruding coupling protrusion 13A formed at the lower end.

In addition, the coupling protrusion 13A is coupled to the upper surface of the front end connector 12 or the connector 13, so that the connector 13 can be continuously buried in the ground.

In addition, the burial is repeated until the tip connector 12 is buried in a hard ground layer.

Further, the cylinder 10 constituting the rotary continuous cylinder 1 is rotated by a rotary motor 15.

The rotary motor 15 used in the rotary continuous cylinder 1 uses a speed control motor to rotate by an input numerical value.

The numerical value is set with a control display connected to the speed control motor, and if a numerical value is set in the control display, rotation and stop are repeated as much as the numerical value.

The loading hole 11 may be formed in plural as necessary, and a fixed spring pin 11A is installed inside one side of the loading hole 11 to fix the tip connector 12 and the connector 13 do.

More specifically, a hydraulic device 16 fixedly installed by a rotating shaft 14 penetrating through the center of the cylinder 10 while positioned at the top of the loading hole 11 is a connection pipe fixed with the fixed spring pin 11A (13) Or, when a hydraulic force is applied to the upper portion of the end connector 12 and pushed, the fixing spring pin 11A holding the connector 13 or the end connector 12 descends downward and the connector 13 Alternatively, since the end connector 12 is automatically released, the connector 13 or the end connector 12 can be buried in the ground.

In addition, the final buried connection pipe 13 uses a threaded connection pipe 13B having a thread formed on the outer circumferential surface, and the threaded connection pipe is coupled with the L-shaped plate fixing nut 13C.

[Steps to remove the rotary continuous cylinder and make the girders connected to the connector through the slide hole]

As shown in Fig. 4, after the end connector 12 is buried to the hard ground layer in the above step, the rotary continuous cylinder 1 is removed.

After removing the rotary continuous cylinder (1), the connecting pipe (13) is coupled to the connecting pipe mounting plate (40) constituting the girder (2) through the slide hole (41), and at this time, the connecting pipe mounting plate (40) ) Couples the connector 13 along the direction of the slide hole 41.

In addition, the pedestal 30 constituting the girder 2 is brought into contact with the bottom surface of the structure so as to support the structure.

Thereby, the girder 2 is combined with the connection pipe 13, but supports the structure floor so that the cracked structure can be lifted.

[Step S50 of fitting the crack of the structure by raising the girder with hydraulic pressure]

As shown in Fig. 4, the girder 2 is combined with the connecting pipe 13, but by supporting the structure bottom surface, the cracked structure can be lifted,

The connection pipe 13 is coupled to the connection pipe mounting plate 40 constituting the girder 2, and the hydraulic device 16 is connected to the connection pipe mounting plate 40 so that the girder 2 can be hydraulically raised. ) It is fixed through brackets 43 and nuts formed on both left and right sides, and when the hydraulic device 16 is operated, the girders 2 are raised along the pair of brackets 43 constituting the girders 2, and at the same time The pedestal 30 constituting the girder 2 supports the bottom surface of the structure, so that when the girder 2 is raised, the crack of the structure with the crack is matched.

In addition, the support 30 forming an L-shape formed on the other side of the girder 2 may have an upper surface, that is, a surface contacting the structure as an uneven surface.

In addition, the upper surface of the pedestal 30 is composed of polyurethane 60 to 70 wt% PVC 30 to 40 wt%, which is a material having friction, to maximize friction.

As a result, the pedestal 30 may stably support or raise the structure by applying a frictional force.

[Step S60 of firmly supporting the structure by making a solid bond using a fixing cap when the structure is raised and the crack of the structure is aligned]

After supporting the connection pipe mounting 40 plate by tightening the L-shaped plate fixing nut (13C) fastened to the upper end of the threaded connection pipe (13B), a pair of second holes are formed on both left and right sides, in the center of the bottom surface. The fixing cap 50 having the mounting protrusion groove 52 formed thereon is coupled to a pair of brackets 43 formed on one side of the connection pipe mounting plate 40 constituting the girder 2 and the connection pipe mounting plate 40 By penetrating and coupling to the upper surface of the connector 13, and fastening the bolts formed at the upper and lower ends of the bracket 43, the connector mounting plate 40 to which the connector 13 is coupled and the fixing cap 50 are securely coupled. And a step (S60) in which the end connector 12, the connector 13, and the girder 2 embedded in the hard ground layer are firmly bonded to each other so that the cracked structure does not crack again. .

Before removing the hydraulic device 16, as shown in Figs. 10 to 11, tighten the L-shaped plate fixing nut 13C fastened to the upper end of the threaded connection pipe 13B to support the connection pipe mounting plate 40 do.

10 to 12, the fixing cap 50 has a pair of second holes 51 formed on both left and right sides, and a mounting protruding groove 52 is formed in the center of the bottom surface.

On one side of the connecting pipe mounting plate 40 constituting the girder 2, a connecting pipe mounting plate 40 to which a pair of brackets 43 and the connecting pipe 13 are combined is formed.

A pair of second holes 51 formed on the left and right sides of the fixing cap 50 penetrates the bracket 43 constituting the girder 2, and the connection pipe 13 is coupled to the connection pipe mounting plate 40 As the upper surface and the mounting protrusion groove 52 of the fixing cap 50 are coupled, the girder 2 and the fixing cap 50 are coupled.

In addition, by tightening the bolts formed at the upper and lower ends of the bracket 43 passing through the second hole 51 of the fixing cap 50, the girder 2 and the connecting pipe 13 are firmly coupled to secure the structure. To support it.

In addition, as shown in Fig. 5, a method of correcting cracks in the structure by pouring back the soil excavated as a finishing operation is achieved.

Hereinafter, it will be described in more detail for the rotary continuous cylinder and the girder.

[Rotating continuous cylinder]

As shown in Figure 6, one side is formed with a plurality of hollow loading holes 11 in the longitudinal direction along the outer circumference, and inside the loading hole, such as a tip connector 12 and a plurality of connector tubes 13 A mounting hole (11A) forming a diameter is formed, the front end connector 12 and a plurality of connector tubes 13 are loaded in the mounting hole 11A, and the rotation shaft 14 is formed through the longitudinal direction in the center. The cylinder 10 rotated by the rotating motor 15,

A casing hole 21A through which the rotation shaft 14 passes is formed in the center, and an open inlet 21 is formed on one side so that the front end connector 12 or the connector 13 can enter the ground, Casing (20) on which the cylinder (10) is mounted

It is formed on the upper side of the loading hole 11 so that the front end connector 12 and the plurality of connector tubes 13 loaded in the electrostatic hole 11 are continuously buried in the ground through hydraulic pressure, and by the rotation shaft 14 It includes a hydraulic device 16 that is fixedly installed, and the loading hole 11 and the hydraulic device 16 and the inlet are located on the same line in the longitudinal direction.

As shown in Fig. 6, the cylinder 10 has a plurality of hollow charging holes 11 formed along the outer circumference. The loading hole 11 is further formed with a hollow mounting hole 11A for mounting the tip connector 12 and the connector 13 therein, and the hollow mounting hole 11A is the connector tube ( 13) It is desirable to achieve a diameter equal to or larger than 0.5 to 1 cm.

It is preferable that the front end connector 12 and the connector 13 are mounted through the hollow mounting hole 11A, and the end connector 12 is first buried in the ground.

It is preferable that the tip connector 12 has a tip-shaped protrusion formed at the lower end, and is designed to be easy to enter the ground.

In addition, a rotation shaft 14 is formed through the center of the cylinder 10, and a support that is bolted to the hydraulic device 16 is formed on one side of the top of the rotation shaft 14 to support the hydraulic device 16, and On one side, a rotational motor 15 for speed control is installed so that the rotational continuous cylinder 1 repeats rotation and stop as much as the input value.

The hydraulic device 16 buries the connecting pipe 13 or the tip connecting pipe 12 deep into the ground through hydraulic pressure.

The hydraulic device 16 is formed at the top of the loading hole 11 to first enter the front end connector 12 mounted in the mounting hole 11A into the ground through hydraulic force, and the end connector 12 ) The connection pipe 13 is buried deep in the ground starting from the front end connection pipe 12 by repeating a series of processes of coupling the upper surface with the coupling protrusion 13A formed at the bottom of the connection pipe 13 and pushing again with hydraulic pressure. .

In addition, as shown in FIG. 8, a fixing spring pin 11A is installed at the lower end of the loading hole 11 to fix the connection pipe 13 or the tip connection pipe 12.

A fixed spring pin (11A) formed at the inner bottom of the loading hole (11) fixes the connection pipe (13) or the tip connector (12), and the hydraulic device (16) fixes the connection pipe (13) or the tip connection When a force is applied to the upper surface of the connection pipe 12 in a downward direction, the pin that was fixed vertically changes to the horizontal direction, and the fixed connection pipe 13 or the end connection pipe 12 is released and is buried in the ground.

In addition, the cylinder 10 is mounted on the casing 20, and an open inlet 21 is formed on one side of the casing 20 so that the connecting pipe 13 and the tip connecting pipe 12 can enter the ground. do.

In addition, the loading hole 11, the hydraulic device 21, and the inlet 21 are on the same line in the longitudinal direction. It is desirable to place it.

[crossbeam]

9, a pedestal 30 formed on one side to form an L-shape;

The slide hole 41 formed on the other side and configured to mount the connector in the horizontal direction and

A connection pipe mounting plate 40 having a pair of first holes 42 formed at both left and right sides of the other side and including a bracket 43 penetrating through the pair of first holes 42;

As shown in Fig. 9, a pair of second holes 51 having the same diameter as the connection pipe mounting plate 40 and through which the bracket 43 passes are formed, and the upper surface of the connection pipe and A fixed mounting protrusion groove 52 is formed to fix the connection pipe 53, and a plurality of bolts formed at the upper and lower ends of the bracket 43 to achieve a solid coupling with the connection pipe mounting plate 40 Includes; cap 50.

As shown in Fig. 10, one side of the girder 2 is provided with an L-shaped pedestal 30. On the other side, a slide hole 41 configured to couple the threaded connector 13B is formed so that it can be coupled with the threaded connector 13B.

When the threaded connector 13B is coupled to the slide hole 41, the hydraulic device 16 is coupled through a pair of brackets 43 and bolts formed on one side of the connector mounting plate.

The hydraulic device 16 is fixed to the bracket 43, and while the hydraulic device 16 is operated, the structure is raised to match the crack of the structure.

After raising the structure, the L-shaped plate fixing nut 13C fastened to the upper end of the threaded connection pipe 13B is tightened to support the connection pipe mounting plate 40

In addition, the connecting pipe mounting plate 40 constituting the girder 2 has a pair of first holes 42 formed on both left and right sides. A pair of brackets 43 pass through the pair of first holes 42.

In addition, the fixing cap 50 fixed on the upper connection pipe mounting plate 40 has the same diameter as the connection pipe mounting plate 40.

The fixing cap 50 has a pair of second holes 51 through which the pair of brackets 43 pass.

In addition, a mounting protrusion groove 52 fixed to the upper surface of the connection pipe is formed in the center of the outer lower end to fix the connection pipe 53.

In addition, a plurality of bolts are formed at the upper and lower ends of the bracket 43, and the connection pipe mounting plate 40 is firmly fixed through the bolts.

More specifically, a pair of second holes 51 formed on the left and right sides of the fixing cap 50 penetrates the bracket 43 constituting the girder 2 and is coupled to the connection pipe mounting plate 40. As the upper surface of the connecting pipe 13 and the mounting protrusion groove 52 of the fixing cap 50 are coupled, the girder 2 and the fixing cap 50 are coupled.

In addition, by tightening the bolts formed at the top and bottom of the bracket 43 passing through the second hole 51 of the fixing cap 50, the girder 2 and the threaded connector 13B are rigidly coupled to form a structure. Make sure to support it firmly.

The present invention easily solves the occurrence of cracks or collapses in an aging structure through a rotary continuous cylinder and a girder, and since continuous safety management is possible even after the structure reinforcement, the safety of the structure is maximized in Japan, Taiwan, India. , Iran, Pakistan, Italy, Portugal, Spain, Peru, Colombia, and other earthquake-prone countries, which are expected to generate great profits, have great industrial applicability.

1: rotary continuous cylinder
2: girder
10: cylinder
20: casing
30: pedestal
40: connector mounting plate
50: fixed cap

Claims (8)

Identifying the crack location of the structure where the crack has occurred, and excavating so that the bottom surface of the structure at the identified crack location is exposed to the outside (S10),

After installing a rotary continuous cylinder in which a plurality of loading holes are formed along the outer circumference at a predetermined interval from the exposed bottom surface,
In the mounting hole configured inside the loading hole, the front end connector and a plurality of connector are loaded, and the cylinder constituting the rotary continuous cylinder and the hydraulic device located on the upper side thereof are on the same line as the mounting hole in which the end connector is loaded. Position it, then
The step (S20) of first burying the tip connector pipe in the ground through a hydraulic device, but penetrating through a guideline formed at a lower side of the cylinder constituting a rotary continuous cylinder;

It has a diameter smaller than the upper surface of the buried end connector, but is buried until it is buried in a solid ground layer by forming a plurality of connecting pipes formed at the lower end of the connecting protrusion protruding so as to be coupled to the upper surface of the end connector. , The final buried connection pipe is buried using a threaded connection pipe having a thread formed on the upper outer peripheral surface (S30), and

After the burial is completed through the step S30, the rotary continuous cylinder is removed, and the bottom surface of the structure is supported by an L-shaped pedestal formed on one side of the girder, and one side of the connecting pipe mounting plate configured on the other side of the girder The step (S40) of coupling with the connector through the slide hole formed in the,

After connecting the hydraulic device with a pair of brackets penetrating the pair of first holes formed on the left and right sides of the connecting pipe mounting plate of the girder, the bracket is hydraulically raised to simultaneously lift the structure supported by the girder to prevent cracking. And matching step (S50),

After supporting the connection pipe mounting plate by tightening the L-shaped plate fixing nut fastened to the upper end of the threaded connection pipe, a pair of second holes are formed on both left and right sides, and a fixing cap having a mounting protrusion groove formed in the center of the bottom surface is provided. A pair of brackets formed on one side of the connecting pipe mounting plate constituting the girder and the connecting pipe mounted with the connecting pipe are coupled by penetrating and coupling to the upper surface of the connecting pipe coupled to the connecting pipe mounting plate, and tightening the bolts formed at the upper and lower ends of the bracket Including the step (S60) of firmly supporting the structure in which the cracked structure does not crack again by forming a solid coupling between the plate and the fixing cap and forming a solid coupling between the tip connector, the connector and the girder embedded in the hard ground layer. In,

The rotary continuous cylinder,

One side is formed with a plurality of longitudinal hollow loading holes along the outer circumference, and a mounting hole having the same diameter as a tip connector and a plurality of connector tubes is formed inside the loading hole, and the tip connector tube is in the mounting hole And a cylinder in which a plurality of connection pipes are loaded, and a rotating shaft is formed through the longitudinal direction in the center, and is rotated by a rotating motor,

A casing hole through which the rotating shaft passes is formed in the center, and an inlet is formed on one side thereof so that the front end connector or the connecting tube can enter the ground, and a casing for mounting the cylinder,

It is formed on the upper side of the loading hole so as to continuously bury the front end connector and the plurality of connector tubes loaded in the loading hole in the ground through hydraulic pressure, and includes a hydraulic device fixedly installed by the rotation shaft, and the loading hole and the hydraulic pressure Fast and smart structure lifting method, characterized in that the device and the entrance are located in the same longitudinal direction.
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