KR101425511B1 - complex cast-in insert apparatus for concrete - Google Patents

Abstract

Provided is a complex cast-in insert device for concrete, including: a support body unit fixed to a mold in which concrete is poured and in which a hollow coupling hole penetrating through the inside is formed; and a lifting body unit having a coupling unit connected to the hollow coupling hole to be selectively moved in a vertical direction by a screw and in which an anchor coupling groove is formed in the inside and a leveling support unit integrally protruding from the outer part in a radius direction along the upper edge of the coupling unit for improving construction convenience by providing a complex function with one device as an anchor is connected to install various kinds of structures on the concrete.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a composite insert-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a composite insert for use in concrete, and more particularly, to a composite insert for concrete, which is provided with an anchor for installing various structures on concrete, ≪ / RTI >

Generally, concrete pouring work is done by making molds according to the shape of the building, injecting the concrete by installing the formwork on the pillar that forms the skeleton of the building, and removing the form when the concrete is dried and cured.

At this time, an anchor for constructing various structures is coupled to the ceiling of the building formed through the concrete, and the anchor can be inserted into the insert embedded in the concrete and be coupled.

Here, as a method for burying the insert in the concrete, there is a post-install method in which the insert is installed after perforating the hole after the concrete curing, and a method of placing the insert in advance and placing the concrete (cast-in) method, and pre-installation method is mainly used.

Figs. 1A and 1B show an example of a conventional insert.

As shown in FIGS. 1A and 1B, a conventional insert 1 has an anchor groove formed on a lower surface thereof. The lower end of the insert 1 is installed on the bottom surface of the mold m, Curing was performed, and formwork (m) was removed, and various structures were installed by joining anchors (a) to the exposed anchor grooves.

In this case, the structure includes a duct, a ceiling board skeleton, an electric wiring, etc., and ceiling construction can be completed by installing various structures on the anchor (a) and connecting the ceiling board along the installed ceiling board framework.

However, when the anchor (a) is supported by the surface of the concrete (c) and a lateral pressure is applied to the anchor (a) Cracks are easily generated and the generated cracks are often propagated to the inside, so that not only the supporting force of the insert 1 is lowered but also the bearing capacity of the concrete c is weakened.

In addition, a gap is frequently formed between the form m and the lower surface of the insert 1 due to foreign matter, so that the concrete c is easily introduced into the anchor grooves, and the introduced concrete c is removed The thread of the anchor groove is often damaged, which makes it difficult to mount the anchor (a).

In order to dispose the reinforcing bar on the side of the concrete slab, a hole is formed in the side wall of the form (m) to insert the reinforcing bar and the concrete has to be laid, so that the form is damaged due to the hole, .

Meanwhile, in order to increase the bearing capacity of the concrete (c), when a reinforcing bar is placed in the concrete (c), a separate reinforcing bar spacer is required to form a reinforcing bar spaced apart from the concrete.

In addition, since unnecessary material cost and installation period are consumed in order to install and provide the insert 1 for the anchor (a) installation and the reinforcing spacer for reinforcing steel reinforcement, the construction cost and the duration are increased, There is a problem that the unnecessary devices are inserted into the inside of the concrete to decrease the bearing capacity of the concrete (c).

Further, since the thickness of the concrete slab is not constant depending on the use or size of the building, if the thickness of the slab is changed and the spacing of the reinforcing bars is changed, a separate spacer corresponding to the spacing of the reinforcing bars must be prepared and installed.

On the other hand, in order to check the horizontal or thickness of the slab when casting the concrete (c), a leveler such as a bar marked with a height was used. In the case of using a product having a long dimension, it is necessary to remove the protruded portion, which is inconvenient for the operation.

As described above, when the concrete (c) is laid, the design and construction are complicated to separately provide and install the insert 1, the reinforcing spacer, the leveler, and the like according to the design of the building, and the construction cost and period are increased, It was hard.

Korea Patent No. 10-0708539

In order to solve the above problems, it is an object of the present invention to provide a composite insert device for a concrete installation, in which an anchor for installing various structures on concrete is combined and a composite function is provided by one device, The problem is solved.

According to an aspect of the present invention, there is provided a method of manufacturing a concrete structure, the method including: providing a support body part fixed to a concrete casting mold, And a lifting body part including a leveling support part integrally projected radially outward along an upper rim of the fastening part, and a lifting body part including a lifting body part integrally formed with the lifting body part, The present invention provides a composite insert device for in-concrete use.

Here, the upper portion of the lifting body may have a water lid covering the boundary between the water and the concrete when the water is absorbed.

At this time, the supporting body portion is formed of reinforced synthetic resin, and a flange portion protruding radially outwardly to be coupled to one surface of the formwork by a coupling means is formed on the outer periphery of the lower end portion, The upper end of the threaded portion formed on the outer periphery is preferably provided with a stopper portion which is engaged with the upper edge of the support body portion and restrains the threaded engagement.

Preferably, the leveling support portion has a plurality of wire insertion holes formed therein for inserting and fastening a reinforcing bar binding wire into the outer circumferential portion thereof. The upper surface of the leveling support portion is preferably provided flat to measure the height of the concrete.

Preferably, an anchor guide portion is formed at a lower portion of the anchor coupling groove so as to guide the anchor downward.

Through the above-mentioned solution, the composite insert device for concrete inlay of the present invention provides the following effects.

First, the support body portion is fixed to the formwork and includes a lifting body portion that is screwed and vertically moved. The leveling support portion of the lifting body portion can be used as a reference surface when the reinforcing bars are fixed and the upper surface is used as a reference surface. , A leveler, and a reinforcing spacer.

Secondly, the elevating body portion can use the upper surface of the leveling support portion as a concrete pouring reference surface, and the reinforcing bars are fixed and supported through the wire insertion holes, and the elevation body is elevated and elevated inside the support body portion. Therefore, when the anchor is installed at each point, It is compatible with reinforcing spacer or leveler as a whole, so that one type of device can be used to carry out the entire construction, so that the convenience of the product can be improved as the construction design and preparation are simplified.

Thirdly, since the lifting body portion is disposed apart from the bottom surface of the formwork, contamination of the inside of the anchor coupling grooves by the concrete introduced into the gap between the formwork and the support body portion is prevented, and the external pressure is not transmitted during the concrete removal of the supporting body portion separately So that damage to the screw structure of the anchor coupling groove is prevented, so that the anchor coupling operation can be facilitated.

Fourth, the lifting body portion is separated from the bottom surface of the formwork and is condensed through the load of the peripheral portion, not the surface portion of the concrete which is vulnerable to cracks, and is supported in the concrete in a firmly coupled state. Therefore, cracking of the concrete due to the lateral pressure is prevented, Since an empty space partitioned by the concrete is formed between the anchor coupled to the fastening portion and the inner circumference of the hollow fastening hole, space efficiency can be improved by minimizing the projecting length of the anchor while providing the anchor flow space, The quality of the construction can be improved.

Fifth, when the support body portion is installed on the side wall portion of the formwork, the ceiling formed of concrete through the anchor engagement groove of the lifting body portion or the joint reinforcing bar protruding to the side of the wall body can be applied without damaging the formwork, Convenience can be improved.

Figures 1a and 1b illustrate a conventional insert.
2 is a cross-sectional view of a composite insert device for concrete in accordance with an embodiment of the present invention.
3 is a plan view of a support body portion of a composite insert device for reinforcing concrete according to an embodiment of the present invention.
FIG. 4 is a plan view of a lifting body of a composite insert device for concrete wear according to an embodiment of the present invention. FIG.
5A, 5B and 5C are schematic views illustrating the use of a composite insert device for concrete in accordance with an embodiment of the present invention.
FIG. 6 is an exemplary view showing a state where a reinforcing bar is coupled to a composite insert device for reinforcing concrete according to an embodiment of the present invention; FIG.
FIG. 7 is an exemplary view showing concrete construction using a composite insert device for concrete in accordance with an embodiment of the present invention; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a concrete composite insert device for concrete according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a plan view of a supporting body portion of a composite insert device for reinforcing concrete according to an embodiment of the present invention. FIG. 4 is a cross-sectional view of the composite insert device for a concrete insert device according to an embodiment of the present invention. 1 is a plan view showing a lifting body portion of a composite insert device for reinforcing concrete according to an embodiment of the present invention.

Here, the concrete composite insert device 100 for concrete use is disposed before being poured so as to be embedded in concrete (see c in FIG. 5C) when forming a ceiling of a building, so that an anchor for installing various structures ) Is inserted and joined.

In addition to anchor installation, it can be used in place of reinforcing spacer for reinforcing steel reinforcement, leveler for measuring the height of concrete pavement, etc., and can be applied to various types of concrete construction, thereby simplifying the construction and preparation of concrete. Can be improved.

As shown in FIGS. 2 to 4, the composite insert device 100 for a concrete according to the present invention includes a support body portion 20 and a lifting body portion 10.

Here, the support body part 20 is fixed to the workpiece m on which concrete is placed, and a hollow fastening hole 21 penetrating the inside of the support body part 20 is formed. At this time, it is preferable that the form m is installed in a support which forms the skeleton of the building to construct the ceiling of the building.

The mold (m) may be formed of various materials, and may be provided as a plywood coated with a release agent along the concrete injection surface so as to be reusable through separation and demolition after concrete curing at the time of general construction.

The support body 20 is fixed to the bottom surface of the mold m and after the concrete is cured, the mold m is removed, and the support body 20 is fixed to the lower surface of the hardened concrete. The lower surface of the base plate can be exposed.

At this time, a hollow fastening hole 21 is formed along the vertical direction inside the support body 20, and the hollow fastening hole 21 can be exposed to the lower surface of the hardened concrete.

Meanwhile, the lifting body 10 includes a fastening portion 10b and a leveling support portion 10a. Here, the fastening portion 10b is screwed to the hollow fastening hole 21 so as to be selectively moved up and down.

At this time, the fastening portion 10b is rotated in one direction in a state of being disposed in the upper opening of the hollow fastening hole 21, and can be inserted into the hollow fastening hole 21, And can be drawn out to the outside of the hollow fastening hole 21.

An anchor coupling groove 16 is formed in the coupling portion 10b to receive an anchor for installation of various structures installed on the ceiling. At this time, the anchor engagement groove 16 is formed on the lower surface of the coupling portion 10b.

Accordingly, when the form m is separated after curing of the concrete, the lower opening of the hollow fastening hole 21 is opened and the anchor is inserted through the lower opening to be coupled to the anchor engaging groove 16 .

Here, it is preferable to understand that the anchor is provided with a diameter of a standard dimension used in a general ceiling construction, and the inner diameter of the anchor coupling groove 16 is dimensioned so that the anchors of the standard dimensions mentioned above can be combined. .

The leveling support portion 10a is integrally projected radially outward along the upper edge of the fastening portion 10b. That is, the leveling support portion 10a is inserted into the concrete, and the lower surface of the protruded portion is supported by the concrete, so that the bonding strength with the concrete can be improved.

Accordingly, when the lifting body 10 is embedded in the concrete, it can be fixed firmly to the inside of the hardened concrete without falling down due to the load of the structure installed on the anchor.

Also, the support body 20 may be fixed to the side wall of the mold m. At this time, when the form m is separated after the concrete curing, the hollow fastening holes 21 are exposed on the sides of the concrete, and the connecting reinforcing bars are inserted through the hollow fastening holes 21, .

Herein, it is preferable to understand that the joint reinforcing bar is a reinforcing bar that is protruded from a side wall of a ceiling or a wall formed of concrete and connected to other reinforcing bars or other structures. Accordingly, the connecting reinforcing bar can be easily assembled without puncturing the form m.

2 to 3, the support body 20 may be formed of reinforced synthetic resin. At this time, the support body 20 may be made of hard and elastic polyvinyl chloride (PVC).

The flange 22 may be provided on the outer periphery of the lower end of the support body 20 so as to be radially outwardly engaged with a surface of the form m by engaging means.

Here, the term 'one side of the form m' means the upper side when the support body 20 is arranged in the up-and-down direction and is used for anchor coupling, and the support body 20 is arranged in the left- It is preferable to understand that the term " side "

At this time, the flange portion 22 may be tightly coupled to the mold m by forming an outwardly bent surface at the lower end of the outer circumference of the support body portion 20. [

When the formwork m is provided as a plywood plate, the fixing nail n is used as a coupling means, and the flange portion 22 is used as a coupling means. May be coupled to the mold (m).

At this time, a nail hole 22a may be formed in the inside of the flange portion 22 and the fixing nail may be inserted into and fixed to the die m through the nail hole 22a The flange portion 22 can be fixed to the mold m.

Of course, the flange portion 22 may be formed by inserting a fixing nail n therein, and an end portion of the fixing nail n is projected to a lower portion of the flange portion 22, As shown in FIG.

At this time, the support body part 20 is disposed at an anchor installation point of the mold m, and an impact is applied to the upper part of the support body part 20 so that the fixing nail n is inserted into the form m, The body portion 20 can be fixed to the mold m.

When the mold m is formed of a material such as fiber-reinforced plastic (FRP), the engaging means may be formed of an adhesive or a double-sided tape. The lower surface of the flange portion 22 An adhesive or a double-sided tape may be applied and bonded to the mold m.

Here, the outer circumference of the support body 20 may have a polygonal columnar shape or a circular columnar shape of a square to octagonal column, but the volume occupied in the concrete is minimized in a state where the hollow fastening hole 21 is formed therein And is preferably provided in a cylindrical shape.

The supporting body portion 20 can support the elevating body portion 10 when the concrete is pushed while being fixed to the formwork m and the elevating body portion 10 Can be supported apart from each other.

Accordingly, even if a gap is formed between the form m and the lower surface of the supporting body portion 20 due to foreign matter, concrete does not flow into the anchor coupling groove 16 and the anchor coupling portion 16 can be maintained without being contaminated.

That is, even if a hole is formed through which the anchor coupling groove 16 can be exposed even if the removal operation such as breaking or scraping of hardened concrete is not performed hardly on the thread of the inner circumference of the hollow fastening hole 21, And can be easily inserted and coupled into the coupling groove 16.

Further, it is necessary to separate the form (m) after the concrete curing and to remove the concrete that has flowed into the support body portion 20.

Since the support body portion 20 is made of an elastic reinforced synthetic resin material and is provided separately from the lifting body portion 10, external force such as pressure or impact externally applied to the concrete body during the concrete removal is applied to the support body portion 20 And can be blocked at the portion screwed with the lifting body 10.

Accordingly, the screw structure of the anchor coupling groove 16 can be prevented from being damaged, for example, by bending the anchor coupling groove 16, so that the anchor coupling operation can be facilitated.

The lifting body 10 is coupled to the workpiece m by the supporting body 20. After the concrete curing, the outside of the lifting body 10 is directly inserted into and bound to the concrete, Can be fixed.

At this time, the lifting body 10 is preferably made of a material having high rigidity, and may be made of reinforced synthetic resin or metal. The present embodiment has been described by taking as an example a steel material having high rigidity.

In detail, since the leveling support portion 10a protruding outward from the outer periphery of the coupling portion 10b is inserted into the concrete, the supporting force against the load can be improved. In addition, the contact area with the concrete is increased through the threaded portion 14 formed along the outer periphery of the coupling portion 10b so as to be screwed into the hollow coupling hole 21, and the coupling force with the concrete through the coupling with the concave- Can be further improved.

In addition, since the elevating body 10 is supported inside the concrete which is condensed through the load of the peripheral portion and firmly coupled with the peripheral portion, rather than the surface portion of the concrete which is vulnerable to cracks, the supporting force against the load is improved, Induced propagation of cracks and cracks can be prevented.

Further, since the outer periphery of the fastening portion 10b in which the anchor is inserted is surrounded by the support body 20 of elastic material, even if a lateral pressure is applied to the anchor, the support body 20 relaxes the pressure It is possible to prevent cracks in the concrete from being damaged.

Further, a clearance space partitioned by concrete may be formed between the anchor coupled to the coupling part 10b and the inner periphery of the hollow coupling hole 21. [

That is, the anchor coupling groove 16 is disposed inside the hollow coupling hole 21 and has an inner diameter smaller than the inner diameter of the hollow coupling hole 21, so that an empty space is formed on the outer periphery of the anchor And the anchors can flow to the left and right in the clearance space and can relieve the lateral pressure.

Since the clearance space is formed inside the hollow fastening hole 21, the protruding length of the anchor for securing the flow of the anchor a is minimized, so space efficiency can be improved.

Further, since the clearance space between the hollow fastening holes 21 and the anchors is partitioned with the concrete, the hollow fastening holes 21 can be made waterproof, sealed, sound-absorbing, etc. without chemical damage to the concrete after the anchor coupling Various finishing treatments can be performed and the quality of the construction can be improved.

For example, in a wet environment, the joint structure of the concrete (c) may be weakened in a finishing process for sealing / waterproofing the joint between the anchor and the anchor coupling groove 16 or preventing noise / Which may be blocked by the support body 20 to prevent it from contacting the concrete.

Accordingly, it is possible to improve the durability of the product, to prevent the insert from being damaged easily by being made of synthetic resin in order to prevent corrosion in a wet environment, or to use an inexpensive stainless steel series The elevating body 10 can be manufactured to provide a high supporting force and can be applied in various construction environments to improve the economical efficiency and reliability of the construction.

The elevating body 10, which is directly coupled to the concrete and provides a supporting force to the anchor, is made of a metal material to provide a firm fixing force, and a supporting body for fixing the elevating body 10 to the formwork The part 20 is made of a synthetic resin to reduce the manufacturing cost by differentiating the material to provide a hard structural force while reducing the production cost, thereby improving the reliability of the product and the production economics.

The upper end of the threaded portion 14 formed on the outer periphery of the coupling portion 10b is engaged with the upper edge of the supporting body portion 20 so as to be coupled to the thread of the inner circumference of the hollow coupling hole 21, It is preferable that the stopper portion 15 be provided.

The threaded portion 14 formed along the outer periphery of the coupling portion 10b is screwed to a thread formed along the inner periphery of the hollow coupling hole 21 and is coupled along the thread when unidirectionally rotated, It can be removed from the thread and raised. Accordingly, the lifting body 10 can be accurately maintained at a raised height without being poured when the concrete is poured.

The stopper portion 15 restricts the depth of insertion of the stopper portion 15 into the hollow fastening hole 21 so as to restrain the screwing to prevent the gap between the lifting body portion 10 and the formwork m from flowing into the concrete It is possible to keep it at more than the interval that can be done.

Furthermore, the reinforcing bars arranged in the concrete can be welded to the outer surface of the stopper portion 15. [ Accordingly, since the lifting body 10 can be more firmly coupled to the concrete and the supporting loads of the respective anchors can be increased, an anchor placement amount for dispersing and supporting the load of the structure can be reduced, It is possible.

2 to 4, a plurality of wire insertion holes 11 are formed in the leveling supporting portion 10a so as to insert and fasten reinforcing wires (see w in FIG. 6) into the outer periphery of the leveling supporting portion 10a, The upper surface 18 of the support portion 10a is preferably flat to measure the height of the concrete.

The leveling support portion 10a may be provided in the shape of a polygonal or circular plate protruding from the upper end of the outer periphery of the coupling portion 10b so as to increase the support area for concrete, It is preferable that it is provided in the shape of a hexagonal plate so as to firmly support the load without being bent when the reinforcing bars are coupled.

At this time, a plurality of wire insertion holes 11 spaced apart from each other by a predetermined distance inward from the rim of the leveling support portion 10a may be formed, and the leveling support portion 10a may be formed in a hexagonal plate shape The wire insertion holes 11 may be formed on the inner side of the corner portions and may be formed one for each of the two corner portions.

In detail, a reinforcing bar binding wire (see w in FIG. 6) can be inserted into each wire insertion hole 11, and the reinforcing bar binding wire can enclose a reinforcing bar disposed below the leveling supporting portion 10a. Here, it is preferable that the reinforcing bar binding wire is a wire used for fixing a reinforcing bar in a general construction site.

The support body 20 may be installed at a position where the anchor is to be coupled to the formwork m and the height of the lifting body 10 may be adjusted to a position of the reinforcing steel fitting position corresponding to the concrete placement height of the construction have.

At this time, when the reinforcing bars are fixed to the leveling support portion 10a, the reinforcing bars are aligned and arranged at a height corresponding to the thickness of the concrete, and can be accurately buried without flowing when the concrete is poured.

Therefore, it is possible to easily place the reinforcing bars at an accurate height without preparing a separate reinforcing spacer or a reinforcing spacer of a size suitable for the height of the concrete casting to be installed at the time of construction, thereby improving the accuracy and convenience of construction.

The wire insertion hole 11 may have a load reinforcing portion 13 extending slantly from the side surface of the coupling portion 10b to support the lower surface of the leveling support portion 10a.

At this time, the load reinforcing portion 13 prevents the leveling supporting portion 10a from being bent downward due to the load of the reinforcing bar or bending upward due to the load of the anchor provided with the structure after the construction, have.

The upper surface 18 of the leveling support portion 10a may be formed flat and a fixing groove 12 may be formed at one side of the upper surface to fix the electronic leveling device (see FIG. 5A). At this time, the leveler may be fixed to the fixing groove 12 or measure the height of the leveling support portion 10a in a state of being mounted on the upper surface 18 of the leveling support portion 10a.

The height of the leveling support portion 10a may be adjusted to correspond to the designed height of the concrete pavement by measuring the height of the leveling support portion 10a through the electronic leveler and rotating the lifting body portion 10. [

At this time, if the height of the leveling support portion 10a is adjusted to the designed concrete pouring height, the electronic leveler is separated and concrete is injected. Here, the upper surface of the leveling support portion 10a may be used as a reference surface to accurately inject the concrete into the designed pouring height.

In this way, if the support body 20 is installed along the position where the anchors are to be coupled, the reinforcing bars are arranged and arranged at an accurate height even if there is no separate reinforcing spacer for reinforcing steel reinforcement or a separate leveler for adjusting the height of the concrete pouring , The concrete can be poured at an accurate height, so that convenience of installation can be remarkably improved.

Thus, the height of the lifting body 10 can be adjusted by providing the supporting body 20 in accordance with the arrangement of the anchors without preparing and installing a reinforcing spacer, a leveler, Function, it is easy to design / prepare for concrete construction.

In addition, it is possible to install the device unified in one unit without installing a separate device in various parts such as the position where the reinforcing bar is supported, the position where the concrete height is measured, the position where the anchor is to be installed, Thereby minimizing the amount of the inner insert to be made, thereby improving the safety of the construction.

In addition, an anchor guide portion 17 may be formed on the lower portion of the anchor coupling groove 16 to extend downward to guide the anchor. Here, the anchor guide portion 17 can be connected to the inner periphery of the anchor coupling groove 16 and the outer periphery of the coupling portion 10b in an upward sloping manner toward the radially inward side.

Accordingly, even if the anchor coupling groove 16 is not visually recognized, if the anchor is pushed along the anchor guide portion 17, the end portion of the anchor can be guided to the inside of the anchor coupling groove 16, Combination work is possible.

The upper portion of the lifting body 10 may be provided with a water lid 30 for sealing the boundary with the concrete c as it absorbs moisture and expands. The level cap 30 covers the top and side surfaces of the leveling support 10a and can be engaged with the bottom surface of the leveling support 10a.

At this time, the level cap 30 may be selectively provided when the leveling support portion 10a is exposed to the outside of the concrete c and used as a leveler, and a position where the concrete c is installed Or in the case of a leakage occurring area such as a kitchen or a bathroom where a water supply / drainage pipe and the like are located.

Here, the water-shielding lid 30 is preferably made of a waterproof material, and may be made of rubber, silicone, or bentonite. Particularly, when the water leakage occurs, the water lid 30 made of the bentonite material expands and can seal the boundary with the concrete more accurately.

For example, when the leveling support portion 10a measures the height of the concrete pouring, the leveling support portion 10a may be exposed to the upper side of the concrete. At this time, the boundary between the concrete and the leveling supporting portion 10a may be vulnerable to leakage.

In addition, since the leveling support portion 10a can be easily broken due to water being introduced between the concrete and the leveling support portion 10a, the supporting force for the anchor and the structure can be reduced.

Moreover, the moisture introduced into the concrete reduces the bonding force between the hardened concrete particles to generate cracks, and the generated cracks can easily propagate to the interior, thereby reducing the durability of the building. At this time, the a-order lid 30 seals the boundary between the leveling support 10a and the concrete to prevent moisture infiltration, thereby improving the safety and reliability of the construction.

Hereinafter, the concrete construction using the above-described composite insert device 100 for concrete construction will be described in more detail.

5A, 5B, and 5C are schematic views illustrating the use of the composite insert device for internal-concrete use according to an embodiment of the present invention. FIG. 6 is a cross- FIG. 7 is a view illustrating an example of concrete construction using a composite insert device for concrete in accordance with an embodiment of the present invention. Referring to FIG.

5a to 7, when the formwork m for pouring the concrete c is installed, the support body 20 is placed on the bottom surface of the workpiece m corresponding to each point where the anchor is to be disposed. And then the concrete (c) is poured.

5A, the electronic leveler j is disposed on the upper surface 18 of the leveling support while the support body 20 is fixed to the mold m, and the electronic leveler j The height of the leveling supporting portion can be adjusted by rotating the elevating body 10 so that the height measured by the height adjusting portion corresponds to the height of the designed concrete pouring height.

5B to 5C, when the height of the leveling support portion is adjusted, the leveling support portion separates the electronic leveler j and the upper portion of the leveling support portion have.

At this time, the car-receiving lid 30 seals between the concrete c and the leveling supporting part, so that moisture can flow into the concrete in a bathroom, a kitchen, a water supply and drainage facility where leakage of water may occur on the concrete c So that it is possible to prevent the rigidity of the concrete from being lowered and the occurrence of cracks.

When the injected concrete c is hardened, the mold m is separated to open the hollow fastening hole and to place the anchor a in the lower part of the hollow fastening hole, To be inserted into the anchor coupling groove.

In this way, the combined function of the anchor insert and the leveler can be performed by one device, and the ease of construction can be improved by simplifying the construction design and preparation.

Referring to FIG. 6, the elevating body 10 can be raised and lowered to the height of the reinforcing bars corresponding to the designed height of the concrete (c), and the reinforcing bars (s) can be inserted by inserting the w (w).

At this time, the concrete (c) is injected into the mold and cured, so that the reinforcing bars (s) can be precisely aligned and placed in the concrete (c) at positions corresponding to the thickness of the concrete (c). Thus, a single device can perform a complex function of the anchor insert and the reinforcing spacer.

Referring to FIG. 7, when the formwork m for concrete construction is installed, the concrete composite insert device 100 for concrete installation can be installed at each point where the anchor a is disposed.

At this time, a part (k) of the devices arranged at each point performs the function of a leveler, and the upper surface of the leveling support portion can be used as a reference plane for raising and lowering the lifting body portion 10 up to the designed concrete pouring height.

The rest of the devices disposed at each point performs the function of a reinforcing spacer, and the elevating body 10 is lifted up to the height of the reinforcing bars corresponding to the height of the concrete pile, .

Since the support body 20 can be installed at each point where the anchor is to be disposed and the elevating body 10 can be elevated and lowered in accordance with the function to be performed and used as a reinforcing spacer or leveler for each point, It is possible to simplify the construction design and preparation, and the convenience of the product can be improved.

Furthermore, it is possible to store various devices such as a reinforcing spacer, a leveler, and an insert separately, to prepare each device as necessary at the time of construction, and to purchase a defective device separately, The convenience of construction can be remarkably improved.

As described above, the present invention is not limited to the above-described embodiments, and variations and modifications may be made by those skilled in the art without departing from the scope of the present invention. And such modifications are within the scope of the present invention.

1: conventional insert a: anchor
c: Concrete m: Formwork
w: reinforcing steel wire s: reinforcing steel
j: electronic leveler 100: insert device
10: lifting body part 10a: leveling supporting part
10b: fastening part 11: wire insertion hole
12: fixing groove 13: load reinforcing portion
14: screw portion 15: stopper portion
16: anchor coupling groove 17: anchor guide portion
20: Support body part 21: Hollow fastening hole
22: flange portion 22a: nail hole
30: Car receiving cover

Claims (5)

A support body part fixed to the mold in which the concrete is cast, in which a hollow fastening hole penetrating the inside is formed;
A lifting body part including a fastening part screwed into the hollow fastening hole so as to be selectively moved up and down and having an anchor coupling groove formed therein and a leveling supporting part integrally projecting radially outward along an upper edge of the fastening part; And
And an augment lid portion provided on an upper portion of the lifting body portion so as to seal the boundary portion with the concrete when the water is absorbed. delete The method according to claim 1,
The supporting body portion is provided with a reinforced synthetic resin and a flange portion protruding radially outwardly to be coupled to one surface of the mold by engaging means is provided on the outer periphery of the lower end portion,
Wherein a stopper portion is provided at an upper end of a threaded portion formed on an outer periphery of the coupling portion so as to be engaged with a thread inside the hollow coupling hole, the coupling portion being engaged with an upper edge of the supporting body portion to restrain the threaded coupling. The method according to claim 1,
Wherein the leveling support portion is formed with a plurality of wire insertion holes through which reinforcing wire is inserted and fastened to the outer periphery of the leveling support portion and the upper surface of the leveling support portion is flatly provided to measure the height of the concrete pouring. Device. The method according to claim 1,
Wherein an anchor guide portion is formed at a lower portion of the anchor coupling groove so as to be extended downward to guide an anchor.

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