KR100795437B1 - Device for Blocking Hollow of Precast Concrete Pile - Google Patents

Abstract

The present invention relates to an anti-cementing device. Conventionally, a device using a connection bar separate from a device for exposing a steel wire in a concrete main wall part constituting a concrete pile is used. The former device is very cumbersome to expose the steel wires, and the strength of the concrete piles may be reduced. The latter device may not be firmly supported by the supporting plate, resulting in insufficient support of the connecting rebar, resulting in poor construction quality. There is a problem. The present invention is provided with spacer support pieces in the block plate support wire connected to the bottom of the block to be inserted into the hollow portion of the concrete piles, spacers to form a coupling portion to support the interruption of the protruding connecting bars while maintaining a certain distance By inserting the pieces into the spacer coupling portion, the support plate of the support plate and the fixing of the connecting reinforcement is firm, so that it is easy to assemble and install while improving the construction quality.

Description

Device for Blocking Hollow of Precast Concrete Pile

1 to 12 show a first embodiment of the anti-cemostatic device according to the present invention,

1 is an exploded perspective view of an anti-cemopreventive device according to the present invention;

Figure 2 is a top perspective view showing an assembled state of the anti-cephaly blocking device according to the present invention,

Figure 3 is a bottom perspective view showing an assembled state of the anti-head blockage device according to the present invention,

4 is a perspective view and a partially enlarged view of the blocking plate according to the present invention;

5 is a cross-sectional view showing a coupling process of the blocking plate and the blocking plate support wire,

6 is a bottom view and a partial enlarged view of the spacer;

7 is a perspective view and a partially enlarged view of the blocking plate support wire;

8 is a perspective view and a partially enlarged view showing a coupling state of the blocking plate and the blocking plate support wire;

9 is a plan view and an enlarged view showing a bonding state of the concrete pile and the blocking plate support wire and spacer,

10 is a partial cutaway perspective view showing a construction state according to the present invention,

11 is a partial cross-sectional view showing a coupling state of the concrete pile and the blocking plate,

12 is a longitudinal sectional view showing a construction process of an anti-cephaly blocking device according to the present invention;

Fig. 13 is a perspective view of a partially cut away state of construction showing a second embodiment of an anti-cephaly blocking device according to the present invention.

** Description of symbols for the main parts of the drawing **

100: blocking plate 200: blocking plate support wire

220: hook 300: connecting rebar

400: high information at the bottom of the connecting bar 500: spacer

610: spacer support 620: coupling portion

621: coupling groove

TECHNICAL FIELD The present invention relates to an apparatus for anti-membrane, and more particularly, to an anti-cemopreventive device that can more easily and firmly support a connecting reinforcing bar inserted into the head.

In general, in the case of building construction structures on the ground and then excavated, concrete piles are installed so that the load of the ground structures is transferred to the support layer through the concrete piles.

Generally, a concrete pile consists of a concrete main wall part formed in the cylindrical cross section which has a hollow part, and the steel wire embedded in this concrete main wall part.

After installing the concrete pile type, the concrete main wall part of the upper part of the concrete pile (approximately 30 cm) is removed to expose the steel wire embedded in the concrete main wall to about 30 cm, and after binding the membrane to the exposed steel wire Concrete (C-class concrete) is filled in the upper part of the hollow part for piles (about 15 cm) to block the top of the concrete pile, and then the foundation reinforcement is poured to lay the foundation concrete.

The process of removing the concrete circumferential wall portion in order to expose the upper portion of the steel wire embedded in the concrete circumferential wall portion of the conventional concrete pile, drilling a plurality of holes in the upper end of the concrete pile, cutting the upper portion of the hole, around the concrete circumferential wall portion Cutting the cutting, cutting the upper portion of the cut portion with a shredder to expose the steel wire, and made through the step of trimming with a hammer.

In addition, in the process of filling the concrete in the upper portion of the hollow part of the concrete pile, inserting the support plate of the membrane cap to a certain depth at the upper end of the hollow part of the concrete pile and supporting the support plate by binding to the steel wire with a plurality of fixed wires; It is made through the step of filling the concrete to block the hollow portion of the upper portion of the base plate at the same time pouring the discarded concrete on the floor.

Thereafter, the foundation floor reinforcement is reinforced and the foundation floor concrete is poured.

At this time, since the upper hollow part of the concrete pile is blocked by the blocking concrete, the raw concrete flows into the hollow part in the process of pouring the foundation floor concrete, thereby preventing the indentation from occurring at the site.

However, in this prior art, care must be taken not to damage the top of the steel wire and the concrete pile in performing the work to expose the steel wire, and the work is performed in several stages using various equipment and tools. Very troublesome, there is a fatal problem in maintaining durability, such as damage to the top of the concrete piles due to the impact during the work process and vertical cracks to reduce the bearing capacity of the concrete piles.

In addition, when the steel wire is damaged, the concrete pile and the foundation floor concrete do not work together, which causes a serious problem in the seismic induced by the horizontal load.

In addition, when installing the cap, the bottom of the fixed wire is bound to the edge of the support plate, and a loop is formed on the upper end to support it by hanging on the steel wire. Therefore, the installation work is cumbersome and the support plate is not installed at the correct position. The gap between the outer circumference prevents the concrete from flowing down, which makes it difficult to fill the concrete and causes the concrete to be wasted.

On the other hand, in order to solve the problems associated with the membrane cap of the above-mentioned conventional problems, hollow portion membrane cap for concrete piles, such as the Utility Model Registration No. 20-0186133 has been conceived.

However, even using the cap of the registration utility model does not solve the problems associated with exposing the steel wire.

In addition, in order to solve the above problems, by adopting a construction method that cuts the head of the concrete pile including the steel wire of the pile and inserts the reinforcing bars in place of the steel wire of the concrete pile, the conventional concrete pile, such as registered utility model 20-0400702 A cap blocking the hollow portion of the hollow, a first support plate spaced a certain distance from the cap and placed on the top of the concrete pile, a second support plate positioned between the cap and the first support plate, and a cap and the first and second support plates. A cap assembly of a foundation engineer pile composed of supported rebars is conceived.

However, in general, concrete piles are loaded with a wire mesh on the mold to inject concrete, and the mold is rotated to fill the concrete by centrifugal force. There is a problem that the work to insert the cap and the second support plate in the hollow of the concrete pile is not practical because it is settled and solidified therein so as not to maintain the circular shape.

In addition, since the cap is to be deformed by tearing the edge by using a steel sheet, the concrete paste leaks, and the latencies are not freely deformed according to the shape of the hollow part where the latencies are settled and solidified. have.

In addition, since the reinforcing bar is welded to the cap and the first and the second support plate made of a steel plate, the strength of the reinforcing bar is not only sharply lowered by the heat of welding, but there is a problem in that the reinforcing cross section is damaged as the reinforcing bar melts.

In addition, since the first support plate is simply mounted on the top surface of the concrete pile, voids are generated between the top surface of the concrete pile and the first support plate, so that the concrete is not completely filled in the voids so that settlement due to the load of the upper structure occurs. There is a problem.

In addition, there is a problem that the production cost is increased as well as the work efficiency is lowered due to the increase in its own weight because the steel sheet is used.

On the other hand, the present inventor (applicant) has developed and applied for the anti-cemostatic device of Patent Application No. 10-2005-0110608 in order to solve the above problems.

In the anti-caking device of the present invention, since the supporting plate is supported on the support constituting the connecting reinforcing means through the connecting reinforcing bar, the load of the connecting reinforcing bar and the blocking concrete is applied to the supporting plate, and thus the supporting plate is hollowed out of the concrete pile. If it is not kept in the negative position to go down, there was a problem that the installation of the blocking concrete and the installation of the connecting reinforcement was not made correctly.

In addition, since the support state of the connecting reinforcing bar is to be unstable state, in order to solidify it is necessary to separate concrete placing process. This prevented concrete pouring has a problem that the work is very cumbersome and requires separate air because the worker has to manually fill each hollow part of each concrete pile.

In addition, in the process of supporting the connecting bar to the support plate and the support, it is necessary to put a separate wedge, so the assembly of the anti-blocking device becomes cumbersome, there is a problem that the work efficiency is lowered and leads to improper construction.

In addition, there is a problem that the manufacturing cost is increased because the injection plate and the support and the wedge should be injection molded.

In addition, the present inventor (applicant) has developed and filed an anti-cementing device of Patent Application No. 10-2005-130383 in order to solve the above problems.

Since the anti-ceiling device of the present invention has a structure in which a spacer supporting the connecting rebar is simply laid over the blocking plate supporting wire which is spread over the top of the concrete pile, the position of the connecting rebar supported by the spacer as the spacer moves randomly during the assembly process. Is not maintained in the correct position, and the blocking plate support wires are scattered, so that the installation work on the inside of the concrete pile is difficult, causing poor construction and deteriorating construction quality. Also, the blocking plate is coupled to the bottom of the blocking plate support wire. There is a problem that the work is delayed due to slipping of the hand in the process.

Therefore, it is an object of the present invention to provide an anti-catheter device that allows easy and convenient assembly and installation process and improves construction quality by maintaining the connection rebar in the correct position.

The present invention and the blocking plate is installed at a predetermined depth of the upper end of the hollow portion of the concrete pile to achieve the above object; A plurality of blocking plate support wires connected to the edge of the blocking plate, an elastic hook formed at a lower end of the blocking plate support wires, a hook formed at an upper end of the blocking plate support wires and covering the upper end of the concrete pile; Blocking plate support means formed on the blocking plate and having a plurality of connecting bosses to which the elastic hooks are connected; A part of a plurality of connecting reinforcing bars inserted into the hollow part and protruding to an upper part of the hollow part, the lower part of which is fixed to the blocking plate; Connecting reinforcing bar bottom support means for supporting a lower end of the connecting reinforcing bar; A spacer having an annular spacer body inserted into an upper end of the hollow part of the concrete pile, and a connecting reinforcing bar support part formed on an inner circumference of the spacer body to support the stopping part of the connecting bar; In the anti-cephaly blocking device comprising a spacer support means for supporting the spacer, The spacer support means is a spacer support piece of the annular bar extending toward the center of the concrete pile at the lower end of the hook of the connecting reinforcing bar support rod, Protruding from the outer peripheral portion of the spacer provides an anti-blocking device comprising a coupling portion having a coupling groove of the C-shaped cross section into which the spacer support piece is inserted.

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The blocking plate support wire is composed of a vertical portion at the bottom, and a portion between the lower end of the hook in the upper portion of the vertical portion is formed with an inclined portion that goes toward the upper portion, a plurality of handle projections are formed on the outer peripheral surface of the vertical portion.

It will be described below in detail according to the embodiment shown in the accompanying drawings the anti-cephaly blocking device according to the present invention.

1 to 12 shows a first embodiment of the anti-cemostatic device according to the present invention, Figure 1 is an exploded perspective view of the anti-cephaly block device according to the present invention, Figures 2 and 3 are 2 is a top perspective view, FIG. 3 is a bottom perspective view, FIG. 4 is a perspective view and a partially enlarged view of the blocking plate according to the present invention, and FIG. 5 is a sectional view showing a coupling process between the blocking plate and the blocking plate support wire. 6 is a bottom view and a partially enlarged view of a spacer, FIG. 7 is a perspective view and a partially enlarged view of a blocking plate support wire, and FIG. 8 is a perspective view and a partially enlarged view showing a coupling state of the blocking plate and the blocking plate support wire. Is a plan view and an enlarged view showing a coupling state of the concrete pile and the blocking plate support wire and the spacer, Figure 10 is a partial cutaway perspective view showing a construction state according to the present invention, Figure 11 is a partial sectional view showing a coupling state of the concrete pile and the blocking plate , 12 is a longitudinal cross-sectional view showing the construction process of the anti-cephaly blocking device according to the present invention.

1 to 11, the anti-blocking device according to the present invention, and the blocking plate 100 is installed at a predetermined depth of the upper end of the hollow portion 13 of the concrete pile 10; Block plate support means for supporting the block plate 100 to the concrete pile (10); A plurality of connecting reinforcement bars (6 in the figure) inserted into the hollow part 13 to protrude to the upper part of the hollow part 13 and fixed to the blocking plate 100; Connecting reinforcing bar bottom support means for supporting a lower end of the connecting reinforcing bar 300; A spacer 500 inserted into an upper end of the hollow part of the concrete pile 10 and supporting a stop of the connecting reinforcement 300 to maintain a spacing of the connecting reinforcement 300; It comprises a spacer support means for supporting the spacer 500.

The blocking plate 100 is formed by a disc part 110 having a diameter smaller than the inner diameter of the hollow part 13 of the concrete pile 10 and a plurality of incision lines 121 at the edge of the disc part 110. The bending piece 120 is divided and the outer diameter is formed to be equal to the inner diameter of the hollow portion 13 of the concrete pile 10, and a plurality of cut lines (three in the example) at the edge of the bending piece 120 ( 131 is divided into a plurality of elastic contact pieces 130, the outer diameter of which is formed larger than the inner diameter of the hollow portion 13 of the concrete pile 10 (see Fig. 4).

As shown in FIG. 3, the reinforcing ribs 111 for reinforcement protrude from the lower surface of the disc part 110.

When the bent piece 120 is formed in an inclined state with respect to the plane of the disc part 110 when viewed from the side, when the blocking plate 100 is inserted into the hollow part 13 of the concrete pile 10. While bending, it is preferable that each of the bending pieces 120 is formed to overlap each other.

The elastic contact pieces 130 are formed on the same plane as each bent piece 120, the inner peripheral surface of the hollow portion 13 when the blocking plate 100 is inserted into the hollow portion 13 of the concrete pile 10 While being in contact with the bending piece 120 is configured to be bent upwardly and in close elastic contact with the inner circumferential surface of the hollow portion 13 by its elasticity.

A bend line 122 is formed between the outer circumference portion of the disc portion 110 and the inner circumference portion of the bending piece 120, and a bending line is formed between the outer circumference portion of the bending piece 120 and the inner circumference portion of the elastic contact piece 130. 132 is formed.

The blocking plate supporting means includes a blocking plate supporting wire 200 connected to an edge of the disc 100 as shown in FIGS. 1 to 3, 7 and 8, and the blocking plate supporting wire 200. It is formed on the elastic hook 210 and the hook ring 220 which is provided at the upper end of the blocking plate support wire 200 and spans the upper end of the concrete pile 10, and the blocking plate 100. It is composed of a plurality of connecting bosses 230 (three in the 120-degree interval in the example shown) is inserted into the elastic hook 210 of the lower end of the blocking plate support wire 200.

As shown in FIGS. 7 and 8, the blocking plate support wire 200 has a lower end portion formed with a vertical portion 201, and a portion between the lower ends of the hook ring 220 is formed at the upper end of the vertical portion 201. It is composed of an inclined portion 202 that opens toward the top.

In addition, the outer circumferential surface of the vertical portion 201 prevents slipping and is easy to work when the elastic hook 210 formed at the lower end of the blocking plate support wire 200 is inserted into the connecting boss 230 formed on the blocking plate 100. A plurality of handle protrusions 203 are formed to be made.

The elastic hook 210 is a pair of elastic pieces 211 and the hook portion 212 protruding from the bottom outer surface of the pair of elastic pieces 211, as shown in Figs. It is composed.

The upper end of the elastic piece 211 of the elastic hook 210 is formed with a cap portion 215 that spans the upper end of the connecting boss 230 when the elastic piece 211 is inserted into the connecting boss 230.

As shown in FIGS. 4 and 5 and 7 and 8, the outer surface of the hook portion 212 is formed with a long and vertical guide protrusion 213 in a horizontal direction, and the connection boss 230. The inner circumferential surface of the hook guide groove 231 is formed in the vertical direction long and horizontal in the horizontal direction to guide the guide protrusion 213, the outer surface of the hook portion 212 corresponding to the hook guide groove 231 In the vertical direction is formed a rotation preventing projection 214 long and narrow in the horizontal direction.

The hook guide groove 231 serves to guide the guide protrusion 213 formed in the hook portion 212 in the process of the elastic hook 210 is inserted into the connecting boss 230, the elastic hook 210 When fully inserted into the connecting boss 230 is to prevent the rotation of the elastic hook 210 and the blocking plate support wire 200 together with the anti-rotation protrusion 214.

The guide protrusion 213 and the anti-rotation protrusion 214 may be formed on either side of the hook portion 212 and the elastic member 211 on each side, respectively, the corresponding hook guide groove 231 is also connected to the boss ( 230) can be formed on either side.

On the other hand, when the elastic hook 210 is inserted into the connecting boss 230, the elastic hook 210 is opened by the elasticity of the elastic piece 211 to prevent the hook portion 212 from being separated from the connecting boss 230. It may be provided with a wedge 240 fitted between the pair of elastic pieces 211 to prevent a more secure connection and leakage of the concrete paste (see Fig. 5).

The blocking plate support wire 200 and the hook ring 220 are integrally formed by a synthetic resin, and a reinforcing wire 221 is embedded in the hook ring 220. That is, the blocking plate support wire 200 and the hook ring 220 are insert molding of the reinforcing wire 221 on the hook ring 220 in the process of integrally molding by synthetic resin (see FIG. 7). .

The connecting reinforcement 300 is that of 13mm standard is used.

As shown in FIGS. 1 to 4 and 11, the connecting reinforcing bar bottom support means is formed integrally with the blocking plate 100 and has a cylindrical shape having a plurality of fastening protrusions 410 on the inner circumferential surface (four in the illustrated example). The bottom of the connection is composed of high information 400.

Here, as shown in FIG. 11, the diameter of the virtual cylinder connecting the inner ends of the tightening protrusions 410 is formed to be larger than the outer diameter of the connecting reinforcement 300 and gradually decreases toward the lower end thereof, thereby connecting the connecting reinforcing bar ( When forming the smaller than the outer diameter of the 300 to drive the connecting reinforcement (300) from top to bottom at the bottom of the connecting reinforcement (400), the fastening protrusion 410 is pressed by the connecting reinforcement (300) and acts as a wedge to connect the reinforcing bar ( The lower end of the 300 is preferably configured to be firmly fixed to the high information 400 under the connecting rebar.

In addition, the bottom of the connecting reinforcing high information 400 is fixed to the bottom of the connecting reinforcement 300 by making the inner diameter of the upper end than the outer diameter of the connecting reinforcement 300, and the lower inner diameter equal to the outer diameter of the connecting reinforcement 300 It is preferable that the connecting reinforcement 300 to be driven into the boss 400 is smoothly inserted into the high information 400 under the connecting reinforcing bar.

The spacer 500 includes an annular spacer body 510 inscribed in a circle smaller than an inner diameter of the hollow part 13 of the concrete pile 10, as shown in FIGS. 1 to 3 and 6, and the spacer Is formed in the inner circumference of the body 510 is composed of a connecting reinforcing bar support portion 520 for supporting the interruption of the connecting reinforcement (300).

The spacer body 510 may be formed in a polygonal (hexagonal) ring shape corresponding to the number (6) of the connecting reinforcement 300 as shown in the example, or may be formed in a circular ring shape.

The connecting reinforcing bar support parts 520 are formed at equal angles on the outer and inner circumferences of the spacer body 510, respectively.

The reinforcing bar interruption support part 520 extends from the inner circumferential side of the spacer body 510 and has an elastic support piece 521 formed to be open at one side to surround a part of the outer circumferential surface of the connecting bar 300, and the elastic support. It is formed of a stopper 522 formed on the opening side of the piece 521 to prevent the connecting reinforcement 300 inserted into the elastic support piece 521 to be randomly separated.

The free end of the elastic support piece 521 is formed with a connecting reinforcing bar guide piece 523 extending in a T-shape with respect to the elastic support piece 521 to guide the connecting reinforcement 300. The inner end of the connecting reinforcing bar guide piece 523 is curved to smoothly guide the connecting bar 300.

The spacer supporting means is a spacer extending toward the center of the concrete pile 10 at the lower end of the hook 220 of the connecting reinforcing rod 200 as shown in FIGS. 1 to 3 and 7 to 9 It comprises a support piece 610 and the engaging portion 620 protruding from the outer peripheral portion of the spacer 500 is supported by the spacer support piece 610.

The spacer support piece 610 is formed to protrude in an annular shape, and the coupling part 620 formed in the spacer 500 is formed to have a coupling groove 621 having a C-shaped cross section with an open lower surface. When the spacer support piece 610 is inserted into the coupling, the spacer support piece 610 may be horizontally moved by the shape of the concrete pile 10, but the spacer support piece 610 may not be randomly separated from the coupling part 620.

The spacer support piece 610 is integrally manufactured in the process of forming the blocking plate support wire 200 and the hook ring 220.

Hereinafter, the process of anti-head blockage by the anti-head blocker according to the present invention will be described.

First, as shown in FIG. 2 and FIG. 3, the blocking plate 100, the blocking plate supporting wire 200 constituting the blocking plate supporting means, the connecting reinforcement 300, and the spacer 500 are separated as shown in FIG. 1. Connect the lower end of the plate support wire 200 to the blocking plate 100, and insert the spacer support piece 610 to the spacer coupling portion 620 so that the blocking plate support wire 200 and the spacer 500 is coupled to Inserting and fixing the lower end of the connecting reinforcement 300 into the cylindrical connecting reinforcement lower end high information 400 constituting the connecting lower end support means, and the stop of the connecting reinforcement 300, the connection reinforcing bar support of the spacer 500 ( 520) to assemble the anti-head blocker according to the present invention.

At this time, in coupling the blocking plate 100 and the blocking plate support wire 200, as shown in FIG. 5, the connecting boss formed on the blocking plate 100 to the elastic hook 210 formed at the bottom of the blocking plate support wire 200 ( The hook portion 212 of the elastic hook 210 is caught by the lower end of the connecting boss 230 by inserting and penetrating from the top to the bottom 230.

In the process of inserting the elastic hook 210 into the connecting boss 230, the guide protrusion 213 formed on the hook portion 212 is guided to the hook guide groove 231 formed on the inner circumferential surface of the connecting boss 230 to connect the boss ( Insertion of the elastic hook 210 to the 230 is made smoothly, in the process of passing the elastic hook 210 through the connecting boss 230, a pair of elastic pieces 211 is deformed inward hook portion When the 212 completely passes through the connecting boss 230, the pair of elastic pieces 211 are restored to their own elasticity and the hook portion 212 is caught by the lower end of the connecting boss 230 (see FIG. 5).

In addition, in the state in which the elastic hook 210 is completely inserted into the connecting boss 230, the anti-rotation protrusion 214 formed on the elastic piece 211 is inserted into the hook guide groove 231 of the connecting boss 230 so that the elastic hook ( Since the horizontal rotation of the 210 is prevented, the blocking plate 100 and the blocking plate supporting wire 200 through the elastic hook 210 are securely connected (see FIG. 5).

In this state, the cap portion 215 is in close contact with the upper end of the connecting boss 230, so that the coupling plate 100 and the blocking plate support wire 200 through the elastic hook 210 is more firmly made.

On the other hand, the elastic hook 210 is to maintain the above-mentioned connection state by the elasticity of the elastic piece 211, as shown in Figure 5 to sandwich the wedge 240 between the pair of elastic pieces 211 It is desirable to be able to prevent a more secure connection and leakage of concrete paste.

In inserting the elastic hook 210 into the connecting boss 230, the worker performs the operation while holding the plurality of handle protrusions 203 formed on the outer circumferential surface of the vertical portion 201 of the blocking plate support wire 200. By doing so, the slip is prevented and the work is easily performed.

In supporting the interruption portion of the connection reinforcement 300 to the reinforcing bar interruption support portion 320 of the spacer 500, the state of the interruption portion of the connection reinforcement 300 is located between the elastic support piece 521 and the stopper protrusion 522. When the force is pushed in, the elastic support piece 521 is opened, and the interruption portion of the connecting reinforcement 300 is inserted between the inner circumferential surface of the spacer body 510 and the elastic support piece 521, and once inserted, the connecting reinforcement 300 ), The outer circumferential surface is caught by the stopper 522 so as not to escape freely (see FIGS. 2 and 3).

In the process of inserting the connecting reinforcement 300 between the inner peripheral surface of the spacer body 510 and the elastic support piece 521, the connecting reinforcing bar guide piece 523 formed at the free end of the elastic support piece 521 is connected to the reinforcing bar ( Since the stop of the 300 is guided, the insertion of the connecting reinforcement 300 to the connecting reinforcing rod stop support 520 is made smoothly so that the operation can be easily performed.

On the other hand, the spacer 500 is inserted into the coupling portion 620 formed on the outer circumferential side of the spacer support piece 610 which is integrally formed in the blocking plate support wire 200 is coupled to each other.

At this time, since the coupling part 620 is formed to have a coupling groove 621 having a C-shaped cross section as shown in FIG. 6, the spacer support piece 610 is coupled to the coupling part 620 in the coupling groove 621. The spacer support piece 610 is inserted into the spacer 610 so as to be horizontally moved from the coupling part 620 so as not to be detached.

Hereinafter, the process of preventing the head of the concrete pile 10 using the anti-blocking device according to the present invention assembled as described above will be described.

As shown in (a) of FIG. 12, the upper end of the concrete pile 10, which is typed on the ruptured floor B, is cut, and the bottom (B) of which the upper end of the concrete pile 10 is broken, as shown in FIG. Protrude 110mm from.

At this time, unlike the prior art, the steel wire 12 is also cut along with the concrete main wall portion 11 of the concrete pile 10 to complete the cutting operation in one operation.

That is, in the prior art, a step of drilling a plurality of holes in the upper end of the concrete pile, cutting out the upper part of the hole, cutting around the concrete circumferential part and trimming with a hammer hammer all proceed to one cutting operation Therefore, the process can be greatly shortened.

Next, the anti-taking device of the present invention assembled as shown in Figure 12 (c) is installed on the upper end of the concrete pile (10).

At this time, the worker performs the operation while holding the upper end of the connecting reinforcing bar 300 of the anti-cephaly blocking device according to the present invention assembled as described above.

The blocking plate 100 is inserted into the upper hollow portion 13 of the concrete pile 10, the hook ring 220 constituting the blocking plate support means coupled to the blocking plate 100 at its lower end is a concrete pile (10) The upper end of the) to support the blocking plate 100, the connecting reinforcement 300 is inserted into the hollow portion 13 by about 400mm from the upper end of the concrete pile 10, at the top of the concrete pile 10 It is installed with protruding about 300mm.

In addition, the blocking plate 100 is in the process of being inserted into the upper hollow portion 13 of the concrete pile 10, the elastic contact piece 130 is in contact with the inner circumferential surface of the hollow portion 13 is generated frictional resistance, manufacturing process In the irregular shape due to the lattices deposited in the concrete pile 10 in the hollow portion 13 according to the shape of the inner circumferential surface bending portion 120 and the elastic contact piece 130 as shown in Fig. 11 while the hollow portion ( The insertion installation process of the blocking plate 100 for 13 is made smoothly.

A bend line 122 is formed between the outer circumference portion of the disc portion 110 and the inner circumference portion of the bending piece 120, and a bending line is formed between the outer circumference portion of the bending piece 120 and the inner circumference portion of the elastic contact piece 130. Since the 132 is formed, the bending pieces 120 and the elastic contact pieces 130 are bent evenly on the basis of the bending lines 122 and 132.

At this time, the bending pieces 120 are inserted into the hollow part 13 of the concrete pile 10 because the bending pieces 120 are formed at a predetermined angle with respect to the plane of the disc part 110 when viewed from the side as shown in FIG. When the bent pieces 120 are overlapped with each other when viewed in the vertical direction, there is no gap between the bent pieces 120.

Next, the discarded concrete 30 is poured into the bottom B which is broken as shown in FIG.

In this case, the blockage device 100 of the present invention is supported by the concrete pile 10 by the blockage plate support wire 200 and the elastic hook 210 and the hook 220 that constitute the blockage plate support means. Therefore, the supporting state is firm and there is no need to pour additional blocking concrete on the upper hollow portion 13 of the blocking plate 100.

When curing of the discarded concrete 30 is completed, as shown in (e) of FIG. 12, the base bottom reinforcing bar 40 is disposed on the upper portion of the discarded concrete 30. At this time, the base reinforcing bar 40 is thicker than the connection bar 300 is used.

Next, the foundation floor concrete 50 is poured on the concrete pile (10).

At this time, the foundation floor concrete 50 is also filled in the upper hollow portion 13 of the blocking plate 100, the foundation floor concrete 50 and concrete pile 10, connecting reinforcement 300 and foundation floor reinforcement 40 This is integrated.

FIG. 13 shows a second embodiment of the anti-cephaly blocking device according to the present invention, which is composed of the blocking plate 100 and the blocking plate supporting wire 200 without using a spacer.

In the present embodiment, the blocking plate 100 is the same as the first embodiment described above, and the blocking plate supporting wire 200 has a hook and an elastic hook 210 except for the spacer support piece 610 of the first embodiment. Since 220 is the same as that of the first embodiment, the same reference numerals are assigned to the same parts, and detailed description thereof will be omitted.

In this embodiment, the assembly of the anti-blocking device is completed by combining the blocking plate 100 and the blocking plate support wire 200 by the elastic hook 210 and the connecting boss 230, and when connecting, Without using the 300, the blocking plate 100 is inserted into the hollow portion 13 of the concrete pile 10, and the hook ring 220 of the blocking plate supporting wire 200 is connected to the upper end of the concrete pile 10. The discarded concrete 30, the foundation floor reinforcement 40 and the foundation floor concrete 50 in the state over.

At this time, the foundation floor concrete 50 is also filled in the hollow portion 13 of the concrete pile 10, the concrete is blocked by the blocking plate 100 is filled in the hollow portion 13 to the lower side of the blocking plate 100. It will not flow down.

According to the anti-ceiling device of the present invention as described above, in the case of installing a separate connecting reinforcing bar in the middle of the concrete pile without exposing the steel wire of the concrete pile, the installation of the connecting reinforcement is made precisely, while being assembled and installed quickly and easily There is an effect that the construction quality is improved.

In addition, according to the anti-cephaly blocking device of the present invention, since the blocking plate and the connecting reinforcing bar is installed in a firmly supported state, it is possible to omit the step of pouring concrete inside the concrete block of a separate concrete pile, and coupling of the blocking plate support wire to the blocking plate. The direction is always maintained accurately, eliminating the need for the correction of the hooks provided on the top of the blocking plate support wire, and thus the construction can be performed quickly and easily.

Claims (4)

A blocking plate installed at a predetermined depth of the upper end of the hollow part of the concrete pile; A plurality of blocking plate support wires connected to the edge of the blocking plate, an elastic hook formed at a lower end of the blocking plate support wires, a hook formed at an upper end of the blocking plate support wires and covering the upper end of the concrete pile; Blocking plate support means formed on the blocking plate and having a plurality of connecting bosses to which the elastic hooks are connected; A part of a plurality of connecting reinforcing bars inserted into the hollow part and protruding to an upper part of the hollow part, the lower part of which is fixed to the blocking plate; Connecting reinforcing bar bottom support means for supporting a lower end of the connecting reinforcing bar; A spacer having an annular spacer body inserted into an upper end of the hollow part of the concrete pile, and a connecting reinforcing bar support part formed on an inner circumference of the spacer body to support the stopping part of the connecting bar; In the anti-catheter device comprising a spacer support means for supporting the spacer, The spacer support means is a combination of a circular rod-shaped spacer support piece extending toward the center of the concrete pile from the lower end of the hook of the connecting reinforcing rod support, and the C-shaped cross section protruding from the outer peripheral portion of the spacer is inserted Anti-catheter device comprising a coupling portion having a groove. delete delete According to claim 1, wherein the blocking plate support wire is composed of a vertical portion of the lower end, and the portion between the lower end of the hook hook from the upper end of the vertical portion is composed of an inclined portion that goes toward the upper, a plurality of handle projections on the outer peripheral surface of the vertical portion Anti-catheter device, characterized in that is formed.

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