KR102747354B1 - Structure outer reinforcement Device - Google Patents

Abstract

The present invention relates to a bridge pier reinforcement device that is fastened to the exterior of a bridge pier whose outer wall is damaged and whose reinforcing bars are exposed to the outside, and which comprises a plurality of structural units that are fixedly connected along the perimeter of the bridge pier, a plurality of cover units that have a preset width and have an internal mounting space formed therein, and each of both ends in the width direction is connected to the structural units and configured to wrap around the perimeter of the bridge pier to form a new outer wall, an internal insertion unit that has a predetermined area, at least a portion of which is provided with an anode material, and is inserted and fixed into the mounting space formed in each of the cover units, and a corrosion prevention unit that has one end connected to reinforcing bars located in a damaged portion of the bridge pier and the other end connected to each of the plurality of internal insertion units, and supplies current to prevent corrosion of the reinforcing bars, and is characterized in that a separate filler is filled in the space between the outer surface of the bridge pier and the cover units.

Description

Structure outer reinforcement device

The present invention relates to a bridge pier reinforcement device having a corrosion prevention function, which is installed separately on the exterior of a bridge pier to form a new outer wall on the exterior of a bridge pier damaged by corrosion or damage, thereby suppressing damage to the bridge pier and maintaining durability.

When structures such as piers, walls, bridges, and buildings age or are damaged by earthquakes or external impacts, additional reinforcement work is required depending on the extent of the damage.

In general, if the damage to the pier is minor, it is possible to reinforce the area by additionally applying mortar or concrete reinforcement to the outer surface, but if the damage is severe or extensive, the entire pier must be replaced or reinforced.

However, there are many situations where it is practically difficult to replace a pier, so it is effective to reinforce the entire pier with reinforcement materials. Accordingly, in cases where the external damage to the pier is severe, a method of reinforcing the exterior of the pier is necessary.

A widely used method of reinforcing a bridge pier in the past was to install reinforcement bars or frames by banding them on the outside of the bridge pier, then form a cylinder-type bulkhead by bonding additional resin plates to the reinforcement bars, and then fill and harden reinforcement materials between the resin plates and the outer surface of the bridge pier.

For reinforcing materials, general cement or mortar, etc. are used, and the exterior of the pier can be reinforced through hardening.

However, in the case of this method, it is difficult to maintain a fixed connection between the reinforcing bar or frame and the resin plate, and if installed in an area subject to frequent earthquakes or external impacts, there is a problem that cracks may occur in the hardened reinforcing material along with the vibration of the resin plate.

If cracks occur in the reinforcing material like this, groundwater can seep in from the ground, causing the resin plate to detach from the frame. In particular, large piers such as bridge piers and walls require careful reinforcement as this can lead to a major accident.

In this way, the reinforcement device of the bridge pier used in the past reinforced the bridge pier by installing a resin plate on the outer surface of the bridge pier and filling the space between with reinforcing material. However, the bonding strength of the resin plate is relatively weak, so it is difficult to maintain durability for a long time even after reinforcement.

In addition, if the steel bars or frames are exposed to the outside, corrosion will occur, significantly reducing durability, and especially if installed at the seaside, there is a problem that corrosion is accelerated by salt.

Therefore, a method to solve these problems is required.

Korean Patent Publication No. 10-2005-0100548

The present invention has been made to solve the problems of the above-mentioned prior art, and has the purpose of providing a bridge pier reinforcement device having a corrosion prevention function, which is installed on a bridge pier whose outer wall has been damaged by wind or waves and whose reinforcing bars have corroded, to form a new outer wall and reinforce it, and at the same time, suppresses corrosion of the reinforcing bars using electric current, thereby ensuring strong durability after reinforcement.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the description below.

In order to achieve the above object, the present invention relates to a pier reinforcement device that is fastened to the exterior of a pier whose outer wall is damaged and whose reinforcing bars are exposed to the outside, and which comprises a plurality of structural units that are fixedly connected along the perimeter of the pier, a plurality of cover units that have a preset width and have an internal mounting space formed therein, and whose opposite ends in the width direction are respectively connected to the structural units and are configured to wrap around the perimeter of the pier to form a new outer wall, an internal insertion unit that has a predetermined area, has an anode material provided in at least a portion thereof, and is inserted and fixed into the mounting space formed in each of the cover units, and a corrosion prevention unit that has one end connected to reinforcing bars located in a damaged portion of the pier and the other end connected to each of the plurality of internal insertion units, and supplies current to prevent corrosion of the reinforcing bars, and a separate filler is filled in the space between the outer surface of the pier and the cover units.

In addition, the corrosion prevention unit is connected to each of the plurality of internal insertion units, and the intensity of the current applied to each of the internal insertion units can be independently controlled according to preset conditions.

In addition, the corrosion prevention unit can be adjusted so that the intensity of the applied current decreases as the distance increases from the internal insertion unit located closest to the damaged rebar.

In addition, the internal insertion unit may include a fixed frame formed along the perimeter corresponding to the shape of the settling space and a positive electrode material formed in a plate or net shape provided inside the fixed frame and a metal sheet portion to which current is applied.

In addition, the fixed frame has at least one through hole formed along the periphery so that a wire extended from the corrosion prevention unit can pass through it and be connected to the metal sheet portion.

In addition, the cover unit may include an outer wall portion having a plate shape of a certain area and an outer surface forming a new outer wall of the pier, a pair of side portions formed by bending toward the pier direction at both ends along the width direction of the outer wall portion, and a connecting portion formed by bending in a direction facing each other at each end of the pair of side portions to form the fixing space between the outer wall portion and the pier, and which is coupled and fixed to the structural unit.

Additionally, the side portion may be configured to have a separate waterproof sealing member provided on at least a portion thereof to seal the interface that comes into contact with an adjacent member.

In addition, the structural unit includes an insertion fixing part having a predetermined length and a protruding shape, one side of which is inserted and fixed into the outer surface of the pier, and a fastening part that is formed by extending from the other side of the insertion fixing part and forming a joining surface of a predetermined area, and the fastening part can be configured to simultaneously join a plurality of the cover units.

In addition, the above-mentioned fastening member is provided with a separate joining member so that it can be detachably joined to the cover unit.

The bridge pier reinforcement device having a corrosion prevention function of the present invention for solving the above-mentioned problem has the following effects.

First, the present invention includes a structural unit formed along the outer circumference of a bridge pier, a plurality of spaced apart structural units installed along the longitudinal direction of the bridge pier, a cover unit coupled to the structural unit, an anode material, and an internal insertion unit installed between the cover unit and the outer wall of the bridge pier, and a corrosion prevention unit respectively connected to exposed reinforcing bars of the bridge pier and the anode material to apply current to suppress corrosion of the reinforcing bars, thereby surrounding and dividing a damaged area of the bridge pier, fixing the anode material, and filling a separate filler, thereby reinforcing the outer wall of the bridge pier and preventing corrosion of the reinforcing bars by applying current.

Second, since an internal insertion unit having an anode material is installed in each of a plurality of cover units and the corrosion prevention unit is connected to the plurality of internal insertion units, the intensity of the current applied to each of the internal insertion units is independently controlled according to preset conditions, thereby making the current applied different depending on the distance between the anode material and the steel bar exposed to the outside of the pier, thereby allowing the charge transfer between the anode material and the steel bar to proceed stably.

Second, it has the advantage of being able to effectively and quickly reinforce the exterior of a pier even when the exterior damage to the pier is severe.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

FIG. 1 is a drawing showing a state in which a bridge pier reinforcement device according to one embodiment of the present invention is installed;
Figure 2 is a side view showing the state in which the bridge pier reinforcement device of the present invention is installed;
Figure 3 is a drawing showing a plane with the bridge pier reinforcement device of the present invention installed;
Fig. 4 is a drawing showing the appearance of a structural unit in the bridge pier reinforcement device of Fig. 1;
Fig. 5 is a drawing showing the appearance of the cover unit in the bridge pier reinforcement device of Fig. 1;
Fig. 6 is a drawing showing the appearance of the internal insertion unit in the bridge pier reinforcement device of Fig. 1;
FIG. 7 is a drawing showing a state in which a structural unit is coupled to a pier in a pier reinforcement device according to one embodiment of the present invention;
Fig. 8 is a drawing showing a state in which a cover unit is combined with the structural units of Fig. 7;
Fig. 9 is a drawing showing a state in which an internal insertion unit is coupled to the cover unit of Fig. 8; and
Figure 10 is a drawing showing a state in which a pier reinforcement device according to an embodiment of the present invention is installed on a pier and filler is injected.

Hereinafter, a preferred embodiment of the present invention, in which the purpose of the present invention can be specifically realized, will be described with reference to the attached drawings. In describing this embodiment, the same names and symbols are used for the same components, and additional descriptions thereof will be omitted.

The bridge pier reinforcement device according to the present invention is a device that is installed on the exterior of a corroded or damaged bridge pier to form a new outer wall to protect it from the external environment, and reinforces it by filling a filler (mortar, concrete) between the new outer wall and the bridge pier. The device is as follows with reference to the attached drawings.

First, a schematic view of a bridge pier reinforcement device according to the present invention will be provided with reference to FIGS. 1 to 3.

The bridge pier (P) reinforcement device according to the present invention largely includes a structural unit (100), a cover unit (200), an internal insertion unit (300), and a corrosion prevention unit (400).

The above structural unit (100) is composed of a plurality of units and is fixedly connected while being spaced apart along the perimeter of the bridge pier (P), and is configured to be connected to the cover unit (200) described below.

Specifically, the above structural unit (100) is a configuration that is installed first to surround the outside of the pier (P), and a plurality of units are spaced apart from each other according to the outer radius of the pier (P), and at least a portion of the units are inserted and fixed on the outer surface of the pier (P).

Here, the above structural unit (100) is formed so that each of the plurality of units has a certain length in the vertical direction and is long, and one side is inserted and fixed into the pier (P). And the cover unit (200) described later is configured to be coupled to the other side.

The above cover units (200) are arranged in multiple units around the perimeter of the pier (P) to surround it, and each unit is connected to the structural unit (100) to form a new outer wall of the pier (P).

Specifically, the cover unit (200) has a preset width and a mounting space (202) is formed inside, so that both ends in the width direction are respectively connected to the structural unit (100).

At this time, the cover unit (200) is formed in a flat or double-angled shape as illustrated, or has a curved outer surface and is configured to wrap around the perimeter corresponding to the shape of the bridge pier (P).

In this embodiment, the cover unit (200) is formed in a flat shape that is elongated in the vertical direction and has a certain width, and is fixed to the structural unit (100) while both ends contact another adjacent cover unit (200).

In this embodiment, the pier (P) is exemplified as having a rectangular cross-section, but this is not limited to this embodiment, and the pier (P) reinforcing device of the present invention can be applied to piers (P) of various shapes, such as circular, polygonal, and horseshoe-shaped.

Meanwhile, the internal insertion unit (300) is formed in a block shape in which a cathode material of a certain area is provided, and is connected to the cover unit (200) and arranged in a form that surrounds at least a portion of the circumference between the outer surface of the bridge pier (P) and the cover unit (200).

In the present invention, the internal insertion unit (300) has a shape corresponding to the shape of the mounting space (202) of the cover unit (200), and a plurality of units are inserted and mounted in each of the cover units (200), and each is provided with the plate-shaped positive electrode material.

That is, the internal insertion unit (300) is configured to place the positive electrode material in a form that wraps around the circumference of the bridge pier (P), but is divided into multiple sections along the circumference so that each can be inserted independently.

In this embodiment, the internal insertion unit (300) is formed in a square shape as shown, and the anode material is arranged in a plate shape in the central portion excluding the edge and is arranged along the perimeter of the bridge pier (P).

Meanwhile, the corrosion prevention unit (400) is configured to supply current to prevent the exposed reinforcing bar (W) from being oxidized in water or air by being installed in the damaged area of the pier (P), and is configured to be connected to the reinforcing bar (W) and the internal insertion unit (300) to supply current.

Specifically, the corrosion prevention unit (400) includes an electrode connection part (410) connected to the reinforcing bar (W), an internal connection part (420) configured independently from the electrode connection part (410) and connected to the internal insertion unit (300), and a supply part (430) connected to each of the internal connection part (420) and the electrode connection part (410) to supply current.

The above electrode connection part (410) and the internal connection part (420) are each formed long with a current-conducting material, one side of which is connected to the reinforcing bar (W) of the pier (P) and the internal insertion unit (300), and the other side extends to the upper part of the pier (P) and is connected to the supply part (430).

At this time, a separate (-) terminal, which is a discharge terminal, is installed in the reinforcing bar (W), and the electrode connection part (410) is connected. Here, before connecting the electrode connection part (410), it is necessary to check whether the reinforcing bar (W) is energized, and it is preferable that the potential difference is measured to be 1 mV or less.

And the above internal connection part (420) is also connected to the electrode connection part (410), and the (+) terminal is connected to the supply part (430).

In the present invention, the internal insertion unit (300) is provided with a plate-shaped positive electrode material, and the internal connection part (420) is connected to the positive electrode material so as to supply current.

In this way, the corrosion prevention unit (400) according to the present invention prevents the steel bar (W) from being corroded by having the electrode connection part (410) and the internal connection part (420) respectively connected to the supply part (430) to receive power.

In the present invention, in the case of a pier (P), the height of the water surface changes due to the influence of weather or the surrounding environment, and in the case of the sea, many changes occur due to waves or tidal differences.

In particular, if the location where the pier (P) is installed is in the sea, salt is dissolved together with the water, so oxygen (O2), water (H2O), and chloride ions (Cl) due to salt always exist, and the rate of early deterioration is high due to the influence of this salt environment.

Accordingly, if the reinforcing bar (W) is exposed to the damaged area of the pier (P), corrosion will accelerate, causing problems with the durability of the pier (P) itself.

And the corrosion prevention unit (400) of the present invention has a similar form to that shown in Korean Patent Publication No. 10-2005-0100548, and prevents corrosion of the reinforcing bar (W) by continuously supplying charge to the reinforcing bar (W).

Next, the corrosion principle of steel bars (W), the principle of the electrical method, and the effect of salt are briefly expressed in equations.

(Formula 1)

(Formula 2)

(Formula 3)

By using the principles of Equations 1 to 3 as described above, the corrosion prevention unit (400) continuously supplies electric charge to the reinforcing bar (W) and minimizes corrosion of the reinforcing bar (W) by maximally suppressing external water and air through the cover unit (200) and filler described below.

Additionally, the corrosion prevention unit (400) according to the present invention may further include a separate photographing unit (not shown) capable of monitoring the connection point between the reinforcing bar (W) and the electrode connection unit (410).

The above-mentioned photographing unit is embedded so that it includes a separate camera so that the camera can capture an image of the reinforcing bar (W) in the pier (P), and an extension line is connected to the upper part of the pier (P) so that the image can be confirmed.

In this embodiment, the photographing unit includes a camera positioned inside the corroded portion of the pier (P) toward the reinforcing bar (W), and the camera is connected to a separate monitor provided at the upper end of the pier (P) so as to confirm an image of the reinforcing bar (W).

In this way, the corrosion prevention unit (400) according to the present invention is connected to the reinforcing bar (W) and the anode material respectively, applies current, and prevents corrosion of the reinforcing bar (W) through the movement of charge between the reinforcing bar (W) and the anode material.

As described above, the bridge pier (P) reinforcement device according to the present invention forms a new outer wall by installing the structural unit (100) on the outer surface of the bridge pier (P) and then combining the cover unit (200), and inserting the internal insertion unit (300) having the anode material into the cover unit (200).

And, the corrosion prevention unit (400) is connected to the reinforcing bar (W) and the internal insertion unit (300), respectively, and a separate filler is filled in the space between the outer surface of the pier (P) and the cover unit (200), and thus, the cover unit (200) is fixed integrally with the pier (P).

At this time, the filler may be a cement-based material such as mortar, cement, or concrete, or a hardenable material such as unsaturated polyester resin or epoxy resin.

The bridge pier (P) reinforced in this manner not only increases strength by reinforcing the bonding state with the bridge pier (P) reinforcing device according to the present invention by the hardened filler, but also prevents corrosion of additional filler (concrete) by blocking external factors surrounding the bridge pier (P) by the cover unit (200).

As described above, the bridge pier (P) reinforcing device according to the present invention has been briefly examined, and the detailed configuration will be examined with reference to FIGS. 4 to 6 below.

FIG. 4 is a drawing showing the appearance of a structural unit (100) in the external reinforcement device of the pier (P) of FIG. 1, FIG. 5 is a drawing showing the appearance of a cover unit (200) in the external reinforcement device of the pier (P) of FIG. 1, and FIG. 6 is a drawing showing the appearance of an internal insertion unit (300) in the external reinforcement device of the pier (P) of FIG. 1.

First, the above structural unit (100) has a certain area, and a part of it protrudes and digs into the outer wall of the pier (P) and is inserted and fixed, and the cover unit (200) is coupled to the other side.

Specifically, the above structural unit (100) is configured to be inserted by a separate drill or pressurizing means after the rust prevention work on the outer wall, and largely includes an insertion fixing part (110) and a fastening part (120).

The above insert fixing member (110) has a certain length and is formed protrudingly so that one side is inserted and fixed on the outer surface of the pier (P). At this time, the insert fixing member (110) is formed long and made of metal or synthetic resin, and one side is inserted into the outer surface of the pier (P) along the longitudinal direction.

And the above-mentioned fastening part (120) is formed to have a certain area and expand on the other side along the longitudinal direction of the above-mentioned insert fixing part (110), and then the above-mentioned cover unit (200) is coupled.

Specifically, the above-mentioned fastening portion (120) is configured such that a joining surface of a certain area is formed, and the plurality of the above-mentioned cover units (200) are simultaneously joined. At this time, the above-mentioned fastening portion (120) has a preset area and is formed in a flat shape, and at least one of the above-mentioned insertion fixing portions (110) is joined in a protruding form on one surface.

In this embodiment, the fastening member (120) is formed in a rectangular shape with a certain area, and a plurality of them are arranged in a group shape in a row along the vertical direction, and each group is arranged spaced apart along the perimeter of the bridge pier (P).

At this time, each of the above fastening parts (120) is formed with a plurality of insert fixing parts (110) and fixedly connected to the outer wall of the pier (P).

Additionally, the fastening member (120) according to the present invention is provided with a separate joining member (230) (130) so that it can be detachably joined to the cover unit (200).

The above-mentioned joining part (230) material (130) is provided on at least a portion of one side of the above-mentioned fastening part (120) and is joined to the cover unit (200). At this time, the joining part (230) material (130) is configured to initially contact and position the cover unit (200), and then a separate adhesive is added so that the cover unit (200) and the fastening part (120) can be completely joined.

In the present invention, the connecting portion (230) (130) is configured in a Velcro form and is capable of being connected, and a portion thereof is provided at a portion of the cover unit (200) that engages with the fastening portion (120) so that it can be configured to be selectively connected or separated by an external force from the user.

In this way, the structural unit (100) according to the present invention includes the insert fixing part (110) and the fastening part (120), and the insert fixing part (110) protruding from the fastening part (120) is inserted and fixed into the outer wall of the pier (P) so that the position of the fastening part (120) can be fixed.

As shown in this embodiment, the structural unit (100) is composed of a plurality of units, and the plurality of units are fixedly connected and spaced apart along the circumference of the pier (P). In addition, the plurality of structural units (100) may be configured to form a group in a form in which they are continuously connected to each other in the vertical direction.

Next, the cover unit (200) has a certain area and is formed in a form that wraps around the outer surface along the perimeter of the pier (P) while being connected to the structural unit (100), thereby forming a new outer wall and at the same time forming a separate space between it and the outer surface of the pier (P).

Specifically, the cover unit (200) has a rectangular outer surface as shown in FIG. 5 and is formed long with a certain length along the vertical direction, and both ends along the width direction are respectively joined and fixed to different structural units (100).

At this time, the structural unit (100) is configured so that two adjacent cover units (200) among the plurality of cover units (200) are simultaneously combined while in contact in the width direction.

The cover unit (200) according to the present invention largely includes an outer wall portion (210), a side portion (220), and a joining portion (230). The outer wall portion (210) has a plate shape with a certain area and the outer surface forms a new outer wall of the pier (P).

Here, the outer wall portion (210) may be composed of a synthetic resin such as PVC or FRP, a thermoplastic resin, a thermosetting resin, etc., and may be formed to have a certain level of elasticity.

In this embodiment, the outer wall portion (210) has a rectangular flat plate shape as shown and has a preset area to form a new outer wall of the pier (P).

And the side portion (220) is formed by bending in the direction of the pier (P) at both ends along the width direction of the outer wall portion (210).

The above side wall portion is a configuration that forms the side surface of the outer wall portion (210) and is formed in a shape that protrudes a certain length from both ends of the outer wall portion (210), and is formed long in the vertical direction to have the same length as the outer wall portion (210).

As shown in this embodiment, the side portion (220) is formed with the same shape on both sides and is formed integrally with the outer wall portion (210).

Here, the side portion (220) is placed in contact with the side portion (220) formed on another adjacent cover unit (200) when the cover unit (200) and the structure unit (100) are combined, and it is preferable that the side portion (220) be formed so as to be in complete contact with each other.

Additionally, the side portion (220) is configured to have a separate waterproof sealing member provided on at least a portion thereof to seal the interface that comes into contact with an adjacent member. At this time, the sealing member is made of rubber or soft synthetic resin, so that the interface between the side portions (220) can be completely sealed when they come into contact with each other.

This can prevent the filling material from leaking to the outside when filling between the cover unit (200) and the outer wall of the bridge pier (P) in the future, and can also prevent moisture or foreign substances from penetrating from the outside into the cover unit (200) and causing damage.

Meanwhile, the above-mentioned connecting portion (230) is formed by bending in a direction facing each other at the ends of the pair of side portions (220) to form the fixing space (202) between it and the outer wall portion (210), and is fixedly connected to the structural unit (100).

Specifically, the above-mentioned connecting portion (230) is formed by bending at the protruding end of the side portion (220) and is spaced apart from the outer wall portion (210) by a certain distance so that the fixing space (202) is formed between them, and the internal insertion unit (300) is subsequently fixed therein.

At this time, the above-mentioned connecting portion (230) is formed by bending at the side portion (220), has a certain area, and is connected to the above-mentioned structural unit (100).

In this embodiment, the connecting portion (230) is arranged in a form parallel to the outer wall portion (210) and is formed to have a width that is relatively smaller than the width of the fastening portion (120). This enables a stable connection state to be maintained by simultaneously connecting two connecting portions (230) to one fastening portion (120) when the cover unit (200) is connected to the structural unit (100) at a later time.

In this way, the cover unit (200) according to the present invention forms the settling space (202) including the outer wall portion (210), the side portion (220) and the coupling portion (230), and is optionally fixedly coupled to the structural unit (100) and forms a new outer wall of the pier (P).

Here, the structural units (100) are arranged along the perimeter of the pier (P) at intervals corresponding to the width of the cover units (200), and the cover units (200) are fixed between a pair of the structural units (100).

Next, the internal insertion unit (300) according to the present invention will be examined with reference to FIG. 6.

The above internal insertion unit (300) is formed in a block shape of a certain size and inserted into the mounting space (202) and is configured to place the positive electrode material between the cover unit (200) and the bridge pier (P), and largely includes a fixed frame (310) and a metal sheet portion (320).

The above fixed frame (310) is configured to form an outer shape, and surrounds the metal sheet portion (320) to maintain its shape, and also to be fixed within the mounting space (202).

Specifically, the fixed frame (310) corresponds to the shape of the settling space (202) and is formed along the perimeter to form an outer shape. At this time, the fixed frame (310) is preferably made of a material that does not conduct current, and in this embodiment, it is made of synthetic resin.

The above metal sheet portion (320) is made of a cathode material having a certain area and is formed in a plate shape or net shape, etc., and is provided inside the fixed frame (310), and the above-described corrosion prevention unit (400) is connected to apply current.

The above metal sheet portion (320) has an area greater than a certain level within the fixed frame (310) and is composed of at least one or more and arranged in a plate or net shape.

In this way, the internal insertion unit (300) fixes the metal sheet portion (320) having the anode material so that the fixed frame (310) maintains its shape, and is inserted into the mounting space (202), and accordingly, the metal sheet portion (320) is fixed at a certain distance from the corroded reinforcing bar (W) of the pier (P).

In this embodiment, the fixed frame (310) is formed as a rectangular frame corresponding to the shape of the cover unit (200), but has a relatively small size, and at least one is inserted and fixed into the mounting space (202). In addition, the metal sheet portion (320) is formed with the positive electrode material in a net shape and is mounted in a rectangular shape inside the fixed frame (310).

At this time, the metal sheet portion (320) is formed in a rectangular shape with a thickness that is relatively thinner than the thickness of the fixed frame (310) and is formed in a shape in which the upper and lower portions and the left and right directions are wrapped by the fixed frame (310).

Here, the fixed frame (310) is configured to have at least one through hole formed along the periphery so that a wire extending from the corrosion prevention unit (400) passes through it and is connected to the metal sheet portion (320).

In this way, the internal insertion unit (300) according to the present invention is formed in a conventional window-type chassis shape, has a metal sheet portion (320) made of the anode material provided in the central portion, and is inserted and fixed into the mounting space (202) while maintaining its shape by the fixed frame (310).

As described above, the bridge pier (P) reinforcement device according to the present invention includes the structural unit (100), the cover unit (200), the internal insertion unit (300), and the corrosion prevention unit (400), and the cover unit (200) is configured to surround the outer surface of the bridge pier (P) by the structural unit (100), and the internal insertion unit (300) is inserted and fixed into each of a plurality of the cover units (200).

Accordingly, the corrosion prevention unit (400) is independently connected to each of the internal insertion units (300) installed inside the cover unit (200) to supply current.

At this time, the corrosion prevention unit (400) is connected to each of the plurality of internal insertion units (300), and the intensity of the current applied to each of the internal insertion units (300) is independently controlled according to preset conditions.

In particular, by varying the current applied depending on the distance between the anode material and the reinforcing bar (W) exposed to the outside at the pier (P), the charge transfer between the anode material and the reinforcing bar (W) can proceed stably.

Specifically, it is preferable that the corrosion prevention unit (400) according to the present invention be adjusted so that the intensity of the applied current decreases as it gets farther away from the internal insertion unit (300) located closest to the damaged reinforcing bar (W).

In addition, the plurality of damaged reinforcing bars (W) have different exposure locations and degrees of damage, and accordingly, the intensity of the current applied to the internal insertion unit (300) at an adjacent location can be adjusted to stably suppress corrosion.

Next, the process of installing a bridge pier (P) reinforcing device according to the present invention will be examined with reference to FIGS. 7 to 10.

FIG. 7 is a drawing showing a state in which a structural unit (100) is coupled to a pier (P) in an external reinforcement device for a pier (P) according to one embodiment of the present invention, and FIG. 8 is a drawing showing a state in which a cover unit (200) is coupled to the structural unit (100) of FIG. 7.

And FIG. 9 is a drawing showing a state in which an internal insertion unit (300) is coupled to a cover unit (200) of FIG. 8, and FIG. 10 is a drawing showing a state in which a filler is injected after an external reinforcement device of a pier (P) according to an embodiment of the present invention is installed on a pier (P).

First, as illustrated in FIG. 7, the bridge pier (P) reinforcing device according to the present invention confirms the location of the exposed reinforcing bar (W) in the damaged area of the bridge pier (P) and then installs a plurality of the structural units (100) along the perimeter of the bridge pier (P) at the corresponding location. At this time, the structural units (100) are arranged along the perimeter in a form that surrounds an area relatively larger than the damaged area of the bridge pier (P), and the structural units (100) are spaced apart at a preset interval.

Here, the above structural units (100) are arranged at preset intervals along the circumference while being connected in a continuous manner in the vertical direction.

In addition, when installing the above structural unit (100), it is desirable to install it by aligning the horizontal level using a reference means such as a string or laser so that multiple fastening parts (120) can be arranged parallel to each other.

Thereafter, the cover unit (200) and the fastening member (120) are mutually connected and form a new outer wall by wrapping the outer surface of the bridge pier (P) as shown in Fig. 8. Here, the fastening member (120) is connected simultaneously with the connecting member (230) of another cover unit (200) positioned adjacently as described above.

At this time, the adjacent cover units (200) are placed with the side portions (220) in contact with each other, and at the same time, the connecting portion (230) is connected to the fastening portion (120).

Accordingly, a new outer wall is formed along the perimeter of the pier (P) in a manner in which the cover unit (200) wraps around the damaged area including the damaged reinforcing bar (W).

Additionally, before combining the cover unit (200) and the structural unit (100), it is preferable to connect the electrode connection part (410) of the corrosion prevention unit (400) to the previously damaged reinforcing bar (W).

Next, the internal insertion unit (300) is combined with the cover unit (200) and the structural unit (100).

Specifically, as illustrated in FIG. 9, the internal insertion unit (300) is formed in a square block shape, has a cathode material provided in the central portion, and is inserted and fixed into the mounting space (202) formed in the cover unit (200).

At this time, the internal insertion unit (300) is formed in a square shape corresponding to the shape of the cover unit (200) and is slidably inserted into the mounting space (202) along the vertical direction. In addition, the internal connection part (420) is connected to the internal insertion unit (300).

Accordingly, the internal insertion unit (300) is inserted and fixed into the cover unit (200), so that the reinforcing bar (W) and the anode material are placed adjacent to each other with a certain distance between them, allowing charge to move.

Finally, as shown in Fig. 10, the filler is filled into the space between the cover unit (200) and the outer surface of the bridge pier (P).

Here, the filler may be a general mortar, and it fills the empty space between the cover unit (200) and the pier (P) and hardens to fix it integrally.

In addition, the filler is filled between the above-mentioned reinforcing bar (W) and the above-mentioned anode material while maintaining a certain gap, thereby stably maintaining the gap and enabling continuous movement of charges.

The bridge pier (P) reinforcing device according to the present invention configured in this manner has the advantage of reinforcing the bridge pier (P) by continuously supplying electric charge to the internal reinforcing bar (W) or frame to prevent corrosion and at the same time forming a new outer wall of the bridge pier (P) to minimize external factors, and can effectively and quickly reinforce the exterior of the bridge pier (P) even in cases where external damage is severe.

In addition, a plurality of cover units (200) each have an internal insertion unit (300) having an anode material installed therein, and a corrosion prevention unit (400) is connected to a plurality of internal insertion units (300), and the intensity of the current applied to each of the internal insertion units (300) is independently controlled according to preset conditions, so that the current applied is varied according to the distance between the anode material and the reinforcing bar (W) exposed to the outside at the pier (P), thereby allowing the charge transfer between the anode material and the reinforcing bar (W) to proceed stably.

As described above, preferred embodiments according to the present invention have been examined, and it is obvious to those skilled in the art that the present invention can be embodied in other specific forms in addition to the embodiments described above without departing from the spirit or scope thereof. Therefore, the above-described embodiments should be considered as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description, but may be modified within the scope of the appended claims and their equivalents.

100: Structural Unit
110: Insert fixing part
120: Fastening
130: Absence of joint
200: Cover unit
210: Exterior wall
220: Side view
230: Joint
300: Internal insertion unit
310: Fixed Frame
320: Metal sheet section
400: Corrosion Protection Unit
W: Rebar
P: Pier

Claims (9)

In a pier reinforcement device that is fastened to the exterior of a pier whose outer wall is damaged and whose reinforcing bars are exposed to the outside,
A structural unit composed of a plurality of pieces and fixedly connected along the perimeter of the above-mentioned pier;
A plurality of cover units having a preset width and having a settling space formed inside, each end of which is connected to the structural unit along the width direction and configured to wrap around the perimeter of the pier to form a new outer wall;
An internal insertion unit having a certain area and having a cathode material at least in a portion thereof and inserted and fixed into the mounting space formed in each of the cover units; and
A corrosion prevention unit having one end connected to the reinforcing bar located at the damaged portion of the above-mentioned pier and the other end connected to each of the plurality of internal insertion units, and supplying current to prevent corrosion of the reinforcing bar;
The above internal insertion unit corresponds to the shape of the above-mentioned settling space and includes a fixed frame formed along the perimeter and a metal sheet portion to which the anode material formed in a plate or net shape is provided inside the fixed frame and to which current is applied.
The above cover unit comprises an outer wall portion having a plate shape of a certain area and an outer surface forming a new outer wall of the pier, a pair of side portions formed by bending toward the pier direction at both ends along the width direction of the outer wall portion, and a connecting portion formed by bending in a direction facing each other at the ends of the pair of side portions to form the fixing space between the outer wall portion and the pier, and is coupled and fixed to the structural unit.
The above internal insertion unit is formed in a square shape corresponding to the shape of the cover unit and is fixed by sliding into the mounting space along the vertical direction so that the steel bar (W) and the anode material are arranged adjacently with a certain distance between them and the charge can move.
A bridge pier reinforcement device characterized in that a separate filler is filled in the space between the outer surface of the bridge pier and the cover unit.
In the first paragraph,
The above corrosion prevention unit,
A bridge pier reinforcement device which is connected to each of the plurality of internal insertion units and in which the intensity of the current applied to each of the internal insertion units is independently controlled according to preset conditions.
In the second paragraph,
The above corrosion prevention unit,
A bridge pier reinforcement device in which the intensity of the applied current is adjusted to decrease as the distance increases from the internal insertion unit located closest to the damaged rebar.
delete In the first paragraph,
The above fixed frame is,
A bridge pier reinforcement device having at least one through hole formed along the perimeter, through which a wire extending from the corrosion prevention unit passes and is connected to the metal sheet portion.
delete In the first paragraph,
The above side part,
A bridge pier reinforcement device configured to seal the interface that comes into contact with adjacent other members by providing a separate waterproof sealing member on at least a portion of the bridge pier.
In the first paragraph,
The above structural unit is,
An insert fixing member having a certain length and formed by protruding and having one side inserted and fixed to the outer surface of the bridge pier; and
A fastening part formed by expanding from the other side of the above insertion fixing part and forming a joining surface of a certain area; including;
The above-mentioned fastening member is a bridge pier reinforcement device configured to simultaneously connect a plurality of the above-mentioned cover units.
In Article 8,
The above-mentioned fastening part is,
A bridge pier reinforcement device having a separate connecting member that is detachably connected to the cover unit.

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