KR101740906B1 - Method for repairing and reinforcing bottom of under water structure - Google Patents

Abstract

The present invention relates to a repair and a reinforcement method of a concrete structure floor for repairing and reinforcing the floor of a concrete structure. The present invention comprises: a step of chipping the floor of a concrete structure; a step of cleaning the chipped floor with high pressure; a step of applying an adhesive to the cleaned floor; a step of laying a reinforcement grid on the floor to which the adhesive is applied; a step of fixing the laid reinforcement grid to the floor by using a fixture; and a step of placing underwater micro-concrete on the floor on which the reinforcement grid is laid. Therefore, the present invention can improve repair performance and reinforcement strength for the floor of the concrete structure by fixing the reinforcement grid to the floor of the concrete structure by the fixture and placing the underwater micro-concrete on the floor of the concrete structure.

Description

TECHNICAL FIELD [0001] The present invention relates to a method for repairing reinforced concrete,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of repairing and reinforcing a floor of a concrete structure, and more particularly, to a method of repairing and reinforcing a floor of a concrete structure to repair and reinforce a damaged area when a floor of a concrete structure, will be.

Causes of deterioration on the bottom of concrete structures generally include freezing and thawing, neutralization, erosion, salt corrosion, rebar corrosion, alkali aggregate reaction, and sulfate attack. Causes of such deterioration occur not in a single deterioration but in a composite deterioration form.

The effect of various deterioration factors on the durability of the concrete structure has been greatly exerted, and there has been a problem that the planned life of the concrete structure is shortened.

In particular, underground structures such as underground wastewater treatment plants or underground sewage systems generate a large amount of harmful gas. In such an environment, corrosion of concrete or structures forming wastewater treatment plant, sewage water pipe to ground water, Developed.

However, even with such a repair method, corrosion is serious due to acidity or alkalinity of harmful gas generated in an environment such as a sewage treatment plant, sewage treatment facility, etc., and the neutralization reaction proceeds rapidly, and thus it is difficult to maintain the facility.

The repair method of concrete structures used up to now is generally a method of repairing the section with polymer mortar and applying an inorganic paint or tar epoxy paint to the bottom of the structure. However, due to moisture, the waterproof layer is exfoliated and peeled, There is a problem in that the work is dangerous due to the harmful gas even during the construction work.

Concrete has generally been recognized to have durability if it meets proper design and construction regulations. However, due to the meteorological and environmental effects experienced during the use of the structure, life span shortening and performance deterioration are frequently observed.

There are many repair and reinforcement methods of these concrete structures. However, most of them have been applied to remove the concrete surface to some extent according to the degree of damage and then to apply coating with repair mortar.

The performance of the concrete structure depends on the bond strength between the reinforcing bars and the concrete that surrounds it. Therefore, when the outer cover is tightly closed, it is possible to prevent deterioration of performance such as corrosion of the reinforcing bar due to external environment, Cracks and the like are generated in a short time due to drying and shrinkage of the water and air, thereby providing a passageway for moisture and air.

In addition, sewage facilities such as sewage boxes and sewer pipes are subject to performance deterioration due to chemical erosion due to rainwater, various polluted water and pollutants. If this performance deterioration persists, freezing and thawing, rebar corrosion, neutralization The durability is deteriorated and the safety is low.

Conventionally, a method of removing a deteriorated portion by a repairing method for a gap formed by corrosion, abrasion and cracking of a sewage system, pouring concrete such as cementitious concrete or mortar, or repairing a cross section by spraying has been used .

Therefore, efforts are being made to improve the performance of concrete structures using coatings of concrete surfaces, resin coatings, and pozzolanic admixtures, but it is difficult to provide satisfactory results due to the lack of material properties, the complexity of construction and economical problems .

The durability of concrete structures is very complex, and the factors that deteriorate durability vary. Therefore, it can not be applied to all areas of this durability by the single method.

In addition, when the concrete structure is damaged, the damaged part is repaired and reinforced. The conventional method is to install and reinforce the concrete by installing scaffolds such as dies and shingles. However, in the repair and reinforcement method, the aged concrete structure can not be effectively reinforced, and a structure such as a formwork is used at the time of work, so that it is difficult to repair and reinforce the work.

In order to solve this problem, a method of repairing and reinforcing a concrete structure without using a structure such as a form has been proposed. This method includes a sandblasting step, a waterproofing step, an anchoring step, The adhesive application step, and the gunning concrete pouring step to repair the concrete structure.

However, in this method, anchoring is performed after the waterproofing treatment, and concrete is placed thereon. However, since many anchor bolts must be connected to the reinforcing bars one by one, and the waterproofing step is complicated and requires drying, And manpower.

In addition, when repairing a damaged part of a concrete structure by using a wire mesh, a wire mesh is installed on a repairing surface, and then concrete or mortar is placed thereon. However, there is a problem that the worker pushes the wire mesh over the finish surface during the installation, and the adhesion between the existing concrete structure and the concrete or mortar newly inserted is weak, resulting in poor durability .

In addition, all of the floor repair and reinforcement methods of concrete structures are required to provide watertight construction as a prerequisite, but since it is impossible to expect complete watertight construction, it is necessary to put concrete under water and realize early strength without losing mortar composition. However, And non-shrinkage polymer cement are used, the curing time and adhesion are not excellent, and the effect of restoring the performance can not be expected.

Korean Patent Publication No. 2001-0037349 (May 07, 2001) Korean Patent No. 10-0647091 (November 23, 2006) Korean Patent No. 10-1404574 (June 09, 2014)

It is an object of the present invention to provide a method of repairing and reinforcing a floor of a concrete structure capable of improving the maintenance performance and reinforcement strength of a floor of a concrete structure.

It is another object of the present invention to provide a method of repairing and reinforcing a bottom of a concrete structure capable of improving the bonding and mixing properties between a reinforcement grid and an underwater micro concrete.

It is another object of the present invention to provide a method of repairing and reinforcing a floor of a concrete structure capable of keeping the depth of the reinforcing grid constant by keeping the reinforcing grid at a predetermined distance from the floor.

It is another object of the present invention to provide a method of repairing and reinforcing a floor of a concrete structure capable of adjusting and securing a separation distance of a reinforcing grid according to a height of a pouring of a micro-concrete underwater.

It is another object of the present invention to provide a method of repairing and reinforcing a floor of a concrete structure, which can exhibit rapid hardness in water and can control the time of shrinkage of the mortar and control the setting time.

According to an aspect of the present invention, there is provided a method of repairing and reinforcing a floor of a concrete structure, the method comprising: chipping a floor of a concrete structure; Washing the chipped bottom with a high pressure; Applying an adhesive to the cleaned floor; Laying a reinforcement grid on the floor where the adhesive is applied; Fixing the deployed reinforcement grid to the floor using a fixture; And placing the micro-concrete underwater on the floor where the reinforcing grid is fixed.

The fixing hole of the present invention is installed on the floor so as to fix the reinforcing grid at a predetermined distance from the floor. The separation distance between the reinforcing grid and the bottom of the present invention is maintained at 10 to 50 mm.

The fixing member of the present invention includes: a supporting piece supported on an upper portion of a floor and supporting a lower portion of a reinforcing grid; A buried piece embedded in the floor to fix the support piece to the floor; And a fixing piece installed on the upper portion of the supporting piece to fix the reinforcing grid.

The underwater microconcrete of the present invention comprises 10 to 12% by weight of Portland cement; 45 to 55% by weight fine fine material; 3 to 5% by weight CA (Calcium Aluminate) cement; 1 to 2% by weight of a curing retarder; 1 to 4 wt% of gypsum or lithium; 1 to 2% by weight of polyethylene oxide; And 25 to 35% by weight of CSA (Calcium Sulfo Aluminate) cement.

The underwater micro-concrete of the present invention is characterized by further comprising 0.1 to 1 wt% of a fluidizing agent.

As described above, according to the present invention, a reinforcing grid is fixed to the bottom of a concrete structure by a fixture, and repair and reinforcement is performed by placing micro-concrete underwater, thereby improving the repair performance and reinforcement strength of the concrete structure Lt; / RTI >

Further, by providing a reinforcement grid, it is possible to improve the bondability and the mixability between the reinforcing grid and the underwater micro concrete.

Also, by providing a fixing hole on the floor so as to fix the reinforcing grid at a predetermined distance from the floor, the reinforcing grid can be spaced apart from the floor by a predetermined distance, thereby maintaining a constant embedding depth of the reinforcing grid.

Further, the provision of the embedment piece, the supporting piece, and the fixing piece as fixing ports provides an effect that the distance of the reinforcing grid can be adjusted and fixed according to the height of the micro-concrete in the underwater.

In addition, by providing portland cement, fine aggregate, CA cement, hardening retardant, hardening accelerator, thickener and CSA cement as underwater micro concrete, it is possible to control the setting time of the mortar while controlling the hardening speed in the water, Effect.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flow chart showing a method of repairing and reinforcing a floor of a concrete structure according to an embodiment of the present invention; FIG.
BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a concrete structure,
3 is a cross-sectional view illustrating a fixation port of a concrete structure floor repair and maintenance method according to an embodiment of the present invention.
4 is a plan view showing a fixture of a concrete structure floor maintenance and repair method according to an embodiment of the present invention.

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

FIG. 1 is a flowchart illustrating a method of repairing and reinforcing a floor of a concrete structure according to an embodiment of the present invention. FIG. 2 is a view illustrating a structure to which a repair and reinforcement method of a concrete structure floor according to an embodiment of the present invention is applied. FIG. 3 is a cross-sectional view illustrating a fixation port of a concrete structure floor according to an embodiment of the present invention, and FIG. 4 is a plan view illustrating a fixture of a concrete structure floor repairing method according to an embodiment of the present invention.

As shown in FIGS. 1 and 2, the repairing and reinforcing method of a floor of a concrete structure according to the present embodiment includes a chipping step S10, a cleaning step S20, a coating step S30, an installation step S40, (S50) and a pouring step (S60). It is a method of repairing and reinforcing a concrete floor to repair and reinforce a floor 100 of a concrete structure such as sewage or stormwater through which running water such as sewage or stormwater flows.

Chipping step S10 is a step of chipping the floor 100 of the concrete structure to remove foreign matter or contaminants attached to the floor 100 of the concrete structure or to remove the corroded or damaged area from the floor.

Such a chipping step may be carried out by using a power tool such as a breaker or the like before repairing and reinforcing the bottom of the structure by freezing and thawing, neutralization, erosion, salt corrosion, corrosion of reinforcing steel, Of course it is possible.

The cleaning step S20 is a step of cleaning the bottoms chipped and chopped in the chipping step S10 with the high pressure cleaning water, using a high pressure washer of 150-200 bar to remove the bottom 100 side of the concrete structure from the high pressure cleaning water High-pressure cleaning to remove various contaminants to clean the cross section.

The reason why the high pressure washer of 150-200 bar is used in the washing step S20 is that if the pressure of the high pressure washer is higher than the above range, there is a possibility that the bottom 100 surface of the concrete structure is damaged, (100) side of the concrete structure is not cleaned.

The applying step S30 is a step of applying the adhesive 10 to the floor cleaned in the cleaning step S20 by applying an adhesion enhancer to the floor 100 side of the concrete structure, To strengthen the adhesive strength to the adhesive.

Such a concrete adhesion enhancer can be applied by using a water-soluble concrete adhesion enhancer made of an acrylic copolymer to provide excellent adhesion to the surface of the bottom 100 of the neutralized concrete structure to enhance adhesion with other materials, It compensates the microcracks of the structure and prevents penetration of harmful substances.

The placing step S40 is a step of laying a reinforcing grid 20 on the surface of the bottom 100 of the concrete structure to which the adhesive is applied in the applying step S30 such that the reinforcing grid 20 is a high strength polyester yarn It is of course possible to use a geogrid having a lattice shape having a gap of approximately 10 to 100 mm.

The fixing step S50 is a step of fixing the reinforcing grid 20 laid in the placing step S40 to the floor using the fixing hole 30 and fixing the reinforcing grid 20 to the concrete structure The bottom 100 of the concrete structure is spaced apart from the bottom 100 of the concrete structure by a predetermined distance.

In addition, it is preferable that the spacing distance h between the reinforcing grid 20 and the bottom 100 of the concrete structure is maintained at 10 to 50 mm. This is because if the distance h is less than 10 mm or higher than 50 mm, the depth of embedding by the micro-concrete under water is low or high, and the reinforcing performance is deteriorated.

The fixture 30 is a support member that is installed in the bottom 100 of the concrete structure so as to fix the reinforcing grid 20 at a predetermined distance from the bottom 100 of the concrete structure, And is an easy spacer fixation port including the embedding piece 31, the support piece 32, and the fixing piece 33 as well.

The embedding piece 31 is a bar-shaped embedding member which is embedded in the bottom 100 of the concrete structure and fixes the supporting piece 32 to the floor and is formed in a shape of a cusp on the lower end to be easily embedded in the bottom 100 of the concrete structure And is formed of a rod member.

The buried piece 31 is composed of a bolt 31a, a head 31b, a nut 31c and a pressing piece 31d. The pressing piece 31d is extended outwardly from the inside of the fixing hole, Needless to say, it is also possible to use a custom anchoring speck.

When the nut 31c is engaged at the lower end of the bolt 31a and the head 31b formed at one end of the bolt 31a is operated, the speed anchor is pressed against the pressing piece 31d And the bolts 31a are inserted into the fixing holes and fixedly engaged with the bolts 31a.

The support piece 32 is a cylindrical support member which is supported on the upper part of the bottom 100 of the concrete structure and is fixed to the lower part of the buried piece 31. The support piece 32 is installed on the bottom 100 of the concrete structure, And a supporting member for supporting a lower portion of the supporting member.

A plurality of fixing holes 32a through which the embedding pieces 31 are inserted and fastened are formed in the upper periphery of the cylindrical supporting piece 32 in the vertical direction. On the upper surface of the supporting piece 32, A coupling protrusion 32c for engaging the fixing piece 33 is formed around the side surface of the support piece 32 so as to protrude .

The fixing piece 33 is a fixing member which is coupled to the upper portion of the supporting piece 32 and fixes the reinforcing grid 20 fitted in the fitting groove 32b of the supporting piece 32, A cover 33a for covering the upper portion of the cover 33a and a cover 33a for fixing the fixing piece 33 to the upper portion of the supporting piece 32 by being engaged with the engaging step 32c of the supporting piece 32, As shown in Fig.

The placing step S60 is a step of placing the underwater micro concrete 40 on the bottom 100 of the concrete structure fixed by the reinforcing grid 20 via the fixing port 30 in the fixing step S50, The concrete 40 is preferably made of a mortar having properties not separated from water.

This underwater micro-concrete 40 is composed of 10 to 12 wt% of Portland cement, 45 to 55 wt% of fine aggregate, 3 to 5 wt% of CA (Calcium Aluminate) cement, A microconcrete containing 2% by weight of a curing retarder, 1 to 4% by weight of a curing accelerator, 1 to 2% by weight of a thickener and 25 to 35% by weight of CSA (Calcium Sulfo Aluminate) desirable.

Portland cement is a finely ground hydraulic cement obtained by mixing a calcareous raw material and a clay raw material in an appropriate ratio. The Portland cement is also known as general cement, and a raw material including silica, alumina, iron oxide and lime is sufficiently mixed at a suitable ratio, An appropriate amount of gypsum is added to the calcined clinker until a part thereof is melted and pulverized to form powder.

It is preferable that such Portland cement has a content of 10 to 12% by weight. The reason for this is that if the value is out of the above range, the property drying performance of the micro-concrete in water is lowered or the dry strength is lowered.

The fine aggregate is a fine aggregate having a particle size of 10 mesh or less and a particle size of 200 mesh or more and is usually composed of an aggregate having a size such that the aggregate passes through a 10 mm sieve and passes through at least 85% by weight in a 5 mm sieve. Preferably, the aggregate has a content of 45 to 55% Do. The reason for this is that the support strength of the underwater micro-concrete deteriorates when the value is out of the above range.

It is needless to say that the fine aggregate may contain 17 to 19 wt% of 8 mm aggregate, 15 to 17 wt% of quartz and 13 to 17 wt% of quartz to increase strength.

CA (Calcium Aluminate) Cement is a calcium aluminate cement mixed with calcium aluminate. It is a factor that improves the expansion and strength of the cured body due to the internal stress during the hydration reaction. Thus exhibiting swellability and fastness.

Preferably, the calcium aluminate cement has a content of 3 to 5% by weight. The reason for this is that expansion of the micro-concrete in water and rapid hardening are lowered when the value is out of the above range.

The hardening retarder is an additive for adjusting the time of the microcrystalline underwater 40 and is made of tartaric acid and preferably has a content of 1 to 2% by weight. This is because it is difficult to control the microcontact time of the underwater microconcrete when the numerical value is out of the above range.

The curing accelerator is an additive for accelerating the setting time of the micro-concrete 40 in water, and is composed of gypsum or lithium carbonate, and preferably has a content of 1 to 4% by weight. This is because it is difficult to control the setting time of the micro-concrete under water if the value is out of the above range.

The thickener is preferably made of polyethylene oxide and has a content of 1 to 2% by weight in order to increase the viscosity of the underwater micro-concrete 40 to prevent the water micro-concrete 40 from being washed away by moisture. This is because the fluidity of the underwater micro-concrete deteriorates when the value is out of the above range.

CSA (Calcium Sulfo Aluminate) Cement is a cement containing a calcium sulfo-aluminate (CSA) type expansion agent, and it is preferably composed of 25 to 35% by weight. The reason for this is that if it exceeds the above-mentioned numerical range, the effect of preventing cracks due to drying shrinkage of underwater micro-concrete is lowered.

In addition, it is needless to say that the underwater micro-concrete 40 of the present embodiment may further comprise 0.1 to 1 wt% of a fluidizing agent. This fluidizing agent is a kind of admixture for concrete, and the admixture for concrete is widely used for improving the quality and workability of concrete as a fourth component after cement, water and aggregate.

Particularly, since the properties of the concrete depend on the fluidity, the fluidizing agent is used to control the dispersion of the cement particles, and in order to have higher fluidity, it is possible to obtain by adding a superplasticizer.

Therefore, the present invention rescues the mortar composition not to be lost when the sewage system is filled with water or when the water flows inside the sewage system, restores the damaged area caused by the acid contained in the cracks and sewage in the sewage system, . ≪ / RTI >

As described above, according to the present invention, it is possible to improve the maintenance performance and reinforcement strength of the bottom of a concrete structure by fixing a reinforcing grid to the bottom of a concrete structure by fixing it with a fixing hole, and inserting and repairing micro- Lt; / RTI >

Further, by providing the reinforcement grid as a reinforcement grid, it is possible to improve the bondability and the mixability between the reinforcement grid and the underwater microconcrete.

Also, by providing a fixing hole on the floor so as to fix the reinforcing grid at a predetermined distance from the floor, the reinforcing grid can be spaced apart from the floor by a predetermined distance, thereby maintaining a constant embedding depth of the reinforcing grid.

Further, the provision of the embedment piece, the supporting piece, and the fixing piece as fixing ports provides an effect that the distance of the reinforcing grid can be adjusted and fixed according to the height of the micro-concrete in the underwater.

In addition, by providing portland cement, fine aggregate, CA cement, hardening retardant, hardening accelerator, thickener and CSA cement as underwater micro concrete, it is possible to control the setting time of the mortar while controlling the hardening speed in the water, Effect.

The present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Therefore, the above embodiments are merely illustrative in all respects and should not be construed as limiting.

10: Adhesive 20: Reinforcement grid
30: Easy spacer anchorage
40: Micro-concrete under water

Claims (6)

As a method for repairing and reinforcing a floor of a concrete structure to repair and reinforce the floor of a concrete structure,
Chipping the bottom of the concrete structure;
Washing the chipped bottom with a high pressure;
Applying an adhesive to the cleaned floor;
Laying a reinforcement grid on the floor where the adhesive is applied;
Fixing the deployed reinforcement grid to the floor using a fixture; And
Placing a micro-concrete underwater on a floor where the reinforcing grid is fixed,
The fixture includes: a support piece supported on an upper portion of a floor and supporting a lower portion of an intersection of the grid-like reinforcement grid; A buried piece embedded in the floor to fix the support piece to the floor; And a fixing piece installed on the upper portion of the supporting piece to fix the reinforcing grid,
Wherein a plurality of fixing holes through which the embedment pieces are inserted and fastened are formed in the upper portion of the support member in a vertical direction, and on the upper surface of the support member, there are formed serration fitting grooves in which intersecting portions of the lattice- And a coupling step for coupling with the fixing piece is protruded from the side surface of the supporting piece. The method according to claim 1,
Wherein the fixing port is installed on the floor so as to fix the reinforcement grid at a predetermined distance from the floor. 3. The method of claim 2,
Wherein a distance between the reinforcing grid and the floor is maintained at 10 to 50 mm. delete The method according to claim 1,
The underwater micro-
10 to 12% by weight of Portland cement;
45 to 55% by weight fine fine material;
3 to 5% by weight CA (Calcium Aluminate) cement;
1 to 2% by weight of a curing retarder;
1 to 4 wt% of gypsum or lithium;
1 to 2% by weight of polyethylene oxide; And
And 25 to 35% by weight of CSA (Calcium Sulfo Aluminate) cement. 6. The method of claim 5,
The underwater micro-concrete further comprises 0.1 to 1 wt% of a fluidizing agent.

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