KR102104599B1 - the high performance precast reinforced concrete pile and the manufacturing method thereof - Google Patents

Abstract

In the present invention, in a pile made of precast in a factory,
An end fixing plate 100;
The main reinforcing bar 200 is fastened to the fixing plate 100 without tension;
A spiral reinforcing bar 300 surrounding the main reinforcing bar 200;
A high-strength concrete 400 that is cast so that the main reinforcing bar 200 and the spiral reinforcing bar 300 are buried therein;
A reinforcement band 500 that wraps around the outer circumferential surface of the high-strength concrete 400 end and is joined to the outer circumferential surface of the fixing plate 100;
Consisting of, including
When the first pile 1000 and the second pile 2000 are joined to each other by welding with the fixing plate 100 facing each other,
Since the reinforcing band 500 of the first pile 1000 and the reinforcing band 500 of the second pile 2000 are continuous,
High performance characterized in that the stress generated from the first pile 1000 is directly transferred to the reinforcing band 500 of the second pile 2000 through the reinforcing band 500 of the first pile 1000. Provides precast RC piles and a method for producing them.

Description

High-performance precast RC pile and its production method {the high performance precast reinforced concrete pile and the manufacturing method thereof}

The present invention relates to a precast pile, and relates to a high-performance precast RC pile of a purchase method that realizes a performance equal to or higher than that of a conventional PHC pile of a steering method and a production method thereof.

1 is a graph showing a test body and test results for evaluating the joint bending performance of a precast RC pile to which a conventional reinforcement band connection structure is applied.

2 is a table showing a conventional pile structure,

3 conceptually illustrates the problem of the existing PHC pile.

Specifically, the existing reinforcing band connection structure of FIG. 1 refers to a fixing plate and a reinforcing band of a joint used in a conventional PHC pile.

Problems such as noise and vibration have been induced in the driving method represented by the existing PHC piles, and the stress of the pile body is large and vulnerable to earthquakes due to a decrease in shear performance.

And, as shown in Figure 1, the bending strength of the joint appears to be less than the breaking moment of the bending strength of the body.

In addition, as shown in Figure 3,

① If the thickness of the fixing plate is thin, the phenomenon of lifting or twisting between the fixing plates may appear,

② If the thickness of the fixing plate is thick, the separation between the concrete and the fixing plate is separated.

A problem has been pointed out that stress transmission does not occur between the upper and lower piles.

Accordingly, the present inventor developed a low-noise, low-vibration precast RC pile, but compared with the PHC pile, has the same or better performance than the PHC pile, and at the same time, joins the fixing plate and the reinforcement band to improve the bending performance and shear performance at the joint. It has led to the development of a high-performance precast RC pile with improved structure and its production method.

[Document 1] Republic of Korea Patent Publication No. 10-2018-0007292 'Pile connection device' January 22, 2018 [Document 2] Republic of Korea Patent Publication No. 10-2018-0007293 'Pile connection device and its manufacturing method' January 22, 2018

The present invention develops a low-noise, low-vibration precast RC pile, but has a performance equivalent to or better than that of a PHC pile, and at the same time, a joint structure of a fixing plate and a reinforcing band to improve bending performance and shear performance at the joint. It is intended to provide a high-performance precast RC pile and a method for manufacturing the same.

In order to solve the above technical problem, the present invention relates to a pile made of precast in a factory,

An end fixing plate 100;

The main reinforcing bar 200 is fastened to the fixing plate 100 without tension;

A spiral reinforcing bar 300 surrounding the main reinforcing bar 200;

A high-strength concrete 400 that is cast so that the main reinforcing bar 200 and the spiral reinforcing bar 300 are buried therein;

A reinforcement band 500 that wraps around the outer circumferential surface of the high-strength concrete 400 end and is joined to the outer circumferential surface of the fixing plate 100;

Consisting of, including

When the first pile 1000 and the second pile 2000 are joined to each other by welding with the fixing plate 100 facing each other,

Since the reinforcing band 500 of the first pile 1000 and the reinforcing band 500 of the second pile 2000 are continuous,

High performance characterized in that the stress generated from the first pile 1000 is directly transferred to the reinforcing band 500 of the second pile 2000 through the reinforcing band 500 of the first pile 1000. Provides precast RC piles and a method for producing them.

According to the present invention, a low-noise, low-vibration precast RC pile was developed, but compared with PHC piles, it has the same or better performance than the PHC pile, and at the same time, the fixing plate and the reinforcement band are joined to improve the bending performance and shear performance at the joint. Provides a high-performance precast RC pile with improved structure and a method for producing the same.

1 is a graph showing a test body and test results for evaluating the joint bending performance of a precast RC pile to which a conventional reinforcement band connection structure is applied.
2 is a table showing a conventional pile structure.
3 conceptually illustrates the problem of the existing PHC pile.
Figure 4 shows a high-performance precast RC pile of the present invention centered around the joints of the first pile and the second pile.
Figure 5 shows the coupling relationship between the fixing plate and the main rebar in the high-performance precast RC pile of the present invention.
FIG. 6 is a photograph of a test body of the high performance precast RC pile of the present invention in which FIG. 5 is implemented.
Figure 7 is a comparison of the cross-section of the precast RC pile of the present invention and the cross-section of the precast RC pile to which the existing reinforcing band connection structure is applied.
8 conceptually illustrates the stress transmission process of the precast RC pile to which the existing reinforcing band connection structure is applied.
9 conceptually illustrates the stress transfer process of the high-performance precast RC pile of the present invention.
10 and 11 compare the structural analysis results of the joint between the precast RC pile to which the existing reinforcement band connection structure is applied and the high-performance precast RC pile of the present invention.
12 and 13 compare the structural analysis results of the joints when the stud bolt is reinforced to the precast RC pile to which the existing reinforcement band connection structure is applied.
14 and 15 compare the results of structural analysis of the joint when the stud bolt is reinforced to the high-performance precast RC pile of the present invention.
16 is a synthesis of the results of FIGS. 10 to 15.
17 shows the specifications of the test body of the high-performance precast RC pile of the present invention.
18 shows a process for manufacturing a test body of a high-performance precast RC pile of the present invention.
19 shows the bending performance and shear performance test process of the test body of the high performance precast RC pile of the present invention.
FIG. 20 shows the measurement position in FIG. 19.
21, 23, and 24 show the bending performance test results of the test body of the high performance precast RC pile of the present invention.
22 and 25 show the shear performance test results of the test body of the high-performance precast RC pile of the present invention.
26 is a time-series procedure diagram of a method for producing a high-performance precast RC pile of the present invention.

Hereinafter, the present invention will be described in more detail through an embodiment in which the concept of the present invention as described above is preferably implemented together with the accompanying drawings.

Ⅰ. High performance Precast RC Pile

Figure 4 shows a high-performance precast RC pile of the present invention centered around the joints of the first pile and the second pile.

High-performance precast RC pile of the present invention, as shown in Figure 4,

In the pre-made stake in the factory,

An end fixing plate 100;

The main reinforcing bar 200 is fastened to the fixing plate 100 without tension;

A spiral reinforcing bar 300 surrounding the main reinforcing bar 200;

A high-strength concrete 400 that is cast so that the main reinforcing bar 200 and the spiral reinforcing bar 300 are buried therein;

A reinforcement band 500 that wraps around the outer circumferential surface of the high-strength concrete 400 end and is joined to the outer circumferential surface of the fixing plate 100;

Consisting of, including

When the first pile 1000 and the second pile 2000 are joined to each other by welding with the fixing plate 100 facing each other,

Since the reinforcing band 500 of the first pile 1000 and the reinforcing band 500 of the second pile 2000 are continuous,

It is characterized in that the stress generated from the first pile 1000 is directly transferred to the reinforcing band 500 of the second pile 2000 through the reinforcing band 500 of the first pile 1000.

Specifically, the main rebar 200 is preferably SD600, H16 standard,

The spiral reinforcing bar 300 is preferably SD500, H10 standard,

The high-strength concrete 400 is desirable to maintain 80Mpa performance.

The reinforcing band 500 may form irregularities as shown in FIG. 4 and the like to improve the binding strength with the high-strength concrete 400 and may be used by joining stud bolts, etc., although not shown.

Figure 7 is a comparison of the cross section of the precast RC pile of the present invention and the cross section of the precast RC pile to which the existing reinforcing band connection structure is applied,

Figure 8 conceptually shows the stress transfer process of the precast RC pile to which the existing reinforcing band connection structure is applied,

9 conceptually illustrates the stress transfer process of the high-performance precast RC pile of the present invention.

The precast RC pile using the existing reinforcing band connection structure,

Reinforcing band is connected to the upper and lower side ends of the fixing plate as shown in Figure 7 (a),

When the two piles are connected to each other, the stress transmitted to the reinforcing band of one pile is not directly transmitted to the reinforcing band of the other pile, as shown in FIG. 8, but is cut off. When the phenomenon of lifting or twisting occurs, or ② when the thickness of the fixing plate is thick, there is a problem in that the separation between the concrete and the fixing plate occurs.

On the other hand, the high-performance precast RC pile of the present invention of the present invention,

As shown in Figure 7 (b), since the reinforcing band 500 is bonded to the outer circumferential surface of the fixing plate 100, the reinforcing band 500 and the second pile 2000 of the first pile 1000 as shown in FIG. The reinforcing band 500 is continuously welded.

Therefore, the stress generated from the first pile 1000 is directly transferred to the reinforcing band 500 of the second pile 2000 through the reinforcing band 500 of the first pile 1000, so the existing problems described in FIG. There is a feature that blocks the source.

10 and 11 compare the structural analysis results of the joint between the precast RC pile to which the existing reinforcement band connection structure is applied and the high-performance precast RC pile of the present invention.

As shown in Figures 10 and 11, the joint in the high-performance precast RC pile of the present invention is the maximum load and yield of the main reinforcing due to the reinforcement band structure of the present invention compared to the precast RC pile to which the existing reinforcement band connection structure is applied. It can be seen that the load was increased.

The high-performance precast RC pile of the present invention may be characterized in that a plurality of stud bolts 600 embedded in the high-strength concrete 400 are joined to the fixing plate 100 for reinforcement.

12 and 13 is a comparison of the structural analysis results of the joint when the stud bolt is reinforced to the precast RC pile to which the existing reinforcement band connection structure is applied,

14 and 15 compare the results of structural analysis of the joint when the stud bolt is reinforced to the high-performance precast RC pile of the present invention.

12 to 15, it can be seen that the maximum load and the yield load of the main reinforcing bar were increased only by adding a stud bolt for shear reinforcement.

Figure 16 is a synthesis of the results of Figures 10 to 15,

The inventor of the present invention derives the high performance precast RC pile of the present invention through the process of FIGS. 10 to 15 several times.

Figure 5 shows the coupling relationship between the fixing plate and the main rebar in the high-performance precast RC pile of the present invention,

FIG. 6 is a photograph of a test body of the high performance precast RC pile of the present invention in which FIG. 5 is implemented.

As shown in Figure 5,

The fixing plate 100 has a fixing hole insertion groove 110 is formed,

The main reinforcing bar 200 is characterized in that it is fastened with a coupler 800 to the fixing device 700 inserted into the fixing device insertion groove 110. 5, the anchorage 700 is composed of an inclined head 730 and a male thread 710, and the anchorage insertion groove 110 is inclined in correspondence with the head 730. A groove 130 is formed, and the main reinforcing bar 200 is formed with a male thread 210, in close contact with the inclined groove 130 so that the head 730 is not exposed to the outer surface of the fixing plate 100. It is installed without sectional defects, and the male thread 710 and the male thread 210 are fastened to both ends of the coupler 800, respectively.

In the present invention, the main reinforcing bar 200 is characterized in that it is installed in an RC manner without tension unlike the existing PHC file.

In the manufacturing process, the coupler 800 has a function of mounting and fixing the end portion of the main reinforcing bar 200 to the fixing plate 100, and a vertical view of the fixing plate 100, which is difficult to maintain due to the fastening of a plurality of main reinforcing rods 200. And adjusting the horizontality with the rotation of the coupler 800.

And, as shown in Figure 6, the fixing plate 100 has a fixing plate fixing hole 130 is formed, the fixing hole insertion groove 110 is inward as much as the concrete coating thickness on the outer peripheral surface of the fixing plate 100 In contrast to being formed, the fixing plate fixing hole 130 is not adjacent to the fixing hole insertion groove 110, and is characterized in that it is formed regardless of the concrete coating thickness on the outer circumferential surface of the fixing plate 100.
Because conventional PHC piles are in the process of production,
In the case of an end formwork that functions as a formwork at the end of a pile corresponding to the fixing plate 100 of the present invention, since a strong tensile force is applied in advance to a steel bar and a production method by centrifugal force is selected.
The formwork fixing hole corresponding to the fixing plate fixing hole 130 of the present invention must be integrally formed with the steel rod fixing hole to install the expanded steel rod to the steel rod fixing hole through the formwork fixing hole for settlement.
In addition, the shape of the steel bar can be prevented from being disturbed due to the flowing concrete by centrifugal force rotating at high speed by binding the fixing plate 100 on which the steel bar (tensile material) is settled to the formwork.

However, the present invention is for producing an RC pile,
The main reinforcing bar 200 of the present invention is difficult to make a head for fixing in the same way as a steel bar due to a node formed on its outer surface. Accordingly, during the centrifugal molding, a fixing hole insertion groove 110 for fixing the main reinforcing bar 200 to the fixing plate 100 is installed in order to maintain the shape of the main reinforcing bar 200, which is to be formed inward as much as the concrete coating thickness on the outer circumferential surface. do. The fixing plate fixing hall 130 should be installed in the same location as the existing formwork of the PHC pile manufacturing plant to produce the RC pile of this name by utilizing the existing production system.
Therefore, it is a feature of the present invention that the fixing hole insertion groove 110 for which the location is selected according to the required covering thickness and the fixing plate fixing hole 130 for connection with the existing formwork are installed separately.

In more detail,
The steel bar used for the existing PHC pile is about 10 mm in diameter, so there is no need to maintain a large concrete coating thickness.
However, the main reinforcing bar 200 of the present invention is about 16 mm in diameter and a spiral reinforcing bar 300 is added so that the reinforcing bar assembly must maintain a large concrete coating thickness.
Therefore, the present invention is to apply the present invention by using the existing PHC pile production line as it is,
Since the position of the fixing plate fixing hole 130 is formed in correspondence with the existing PHC pile production line,
The formation position of the fixing hole insertion groove 110 in which the main reinforcing bar 200 is installed is formed inside the fixing plate fixing hole 130 due to the increased concrete coating thickness.

17 shows the specifications of the test body of the high-performance precast RC pile of the present invention,

18 shows a process for manufacturing a test body of a high-performance precast RC pile of the present invention.

Figure 19 shows the bending performance and shear performance test process of the test body of the high-performance precast RC pile of the present invention,

FIG. 20 shows the measurement position in FIG. 19.

21, 23, and 24 show the bending performance test results of the test body of the high performance precast RC pile of the present invention.

As shown, all of the test specimens of the high-performance precast RC pile of the present invention are evaluated to satisfy the bending performance because they are greater than the nominal bending strength level (145.3 kN). In addition, the RC500-F-NJ specimen (integrated type) showed greater ductility behavior than the specimen with joints, and the maximum load was evaluated to be about 15-20% higher.

In addition, when comparing the load level to a displacement of about 90mm, the RC500-FJ (1) and (2) specimens are judged to have a reinforcement effect on the joints at 93% and 94%, respectively, at the same displacement as the RC500-F-NJ specimens. .

That is, compared to the existing non-reinforced joint specimen, the specimen of the present invention reinforced in both structural rigidity and maximum load shows a large level.

22 and 25 show the shear performance test results of the test body of the high-performance precast RC pile of the present invention.

As shown, the test specimens of the high-performance precast RC pile of the present invention are 573.1 kN (RC500-S-NJ) and 496.7 kN (RC500-SJ (1), respectively) when calculating the maximum shear force in consideration of the weight of the specimen 2.7 kN / m. , 596.5 kN (RC500-SJ (2)).

Compared with the nominal shear strength (530.1kN), the structural performance is satisfactory except for the RC500-S-J (1) test specimen.

In the case of RC500-S-J (1) specimen, it is judged that the maximum load or the maximum shear force is reduced due to eccentric load and crack,

In the case of the joint test body (RC500-S-J (1), (2)), it shows a large ductility behavior compared to the integral test body (RC500-S-NJ). Specifically, the shear specimen (spiral rebar) yields to the joint specimen, and the integral specimen exhibits compressive fracture behavior of the abdominal concrete.

Ⅱ. High performance Precast RC pile  Production method

FIG. 18 shows a process for manufacturing a test body of a high-performance precast RC pile of the present invention, and FIG. 26 is a time-series procedure of the method for producing a high-performance precast RC pile of the present invention.

The method of producing a high-performance precast RC pile of the present invention is for producing the high-performance precast RC pile,

(1) a main rebar thread processing step of forming a thread at the end of the main rebar 200;

(2) a rebar assembly completion step of joining the spiral reinforcing bar 300 to the main reinforcing bar 200;

(3) a joint reinforcement step of joining the reinforcing band 500 and the stud bolt 600 to the fixing plate 100;

(4) a reinforcing bar assembly step of fastening the main reinforcing bar 200 to the fixing plate 100 using the fixing tool 700 and the coupler 800;

(5) the installation step of the formwork fixing the fixing plate fixing hole 130 and the formwork of the fixing plate 100 installed at the end of the reinforcing bar assembly;

(6) placing a high-strength concrete to pour the high-strength concrete 400 inside the formwork;

(7) a centrifugal molding step of rotating the assembly of the fixing plate 100 and the formwork;

(8) steam curing step of curing the high-strength concrete 400 by applying steam;

Characterized in that it comprises a.

And the (5) formwork installation step is characterized in that to install a spacer and install the rebar assembly in the formwork so as to maintain the coating thickness.

The spacer is a spacer that functions to maintain the reinforcement position of the reinforcing bar from the centrifugal force in the (7) centrifugal forming step and to maintain the concrete coating thickness in the (6) high-strength concrete pouring step and the (8) steam curing step. You can use (spacer) or use a piece of iron.

In addition, the high-performance precast RC pile of the present invention is constructed to be drilled in a perforated hole by perforating a plurality of ground holes to correspond to the depth of the perforated hole at the construction site.

However, the high-performance precast RC pile of the present invention is compatible with other types of piles such as existing PHC piles or steel pipe piles, thereby realizing a composite pile method,

Specifically, the construction may be performed by connecting to other types of piles shown in FIG. 2 according to the field conditions and the design book, or, in some cases, a purchase method may be installed on the top of piles installed in a driving manner at the bottom.

Specific specifications of the high-performance precast RC pile of the present invention are as follows.

(1) The high-performance precast RC pile of the present invention should be of a safe structure under the design load of the extreme limit state and the extreme state limit state. It is desirable to reinforce the fixing plate with studs and apply welding joints for smooth stress distribution of the joints.

(2) When the joint is installed, the length of the upper pile is preferably 10 times or more (or 3 / β) of the pile diameter.

(3) The flexural strength test of the joint can match the joints in the center of the span and suggest the strength reduction coefficient and displacement effect in the extreme limit state and extreme situation limit state of the joint according to the results of the flexural strength test.

(4) The flexural strength test of the joint can be presented by comparing the load-deflection change curve with that of a member without a joint until the member reaches a fracture condition.

(5) The joint strength of the high-performance precast RC pile of the present invention can be determined by experiment according to KDS 24 14 21 (1.4.2.5 (2)), and the resistance correction factor is suggested according to the joint type. It must satisfy the design conditions of the extreme limit state and the extreme limit state.

(6) In the case of the welded joint type, the strength reduction factor of 0.85 should be additionally applied to the design strength of the pile body under the extreme and extreme limit conditions, and the allowable value of displacement calculated by the displacement method under the used limit is 27 mm. (10.5mm for alternation) is applied. However, 0.9 is applied for the strength reduction factor of the second joint or less on the ground.

(7) It is desirable to plan the position of the first joint on the ground so that the length of the upper pile is 10 times or more (or 3 / β) of the pile diameter.

(8) If the length of the upper pile is smaller than the design value due to the depth change of the bedrock during construction, the design value acting on the joint should be recalculated and the safety of the joint should be checked.

(9) The cross section of the joint should be perpendicular to the axis of the high-performance RC pile.

The present invention has been described in connection with the preferred embodiment as mentioned above, but various modifications and variations are possible within the scope without departing from the gist of the present invention, and can be used in various fields.

Accordingly, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

100: fixing plate
110: anchorage insertion groove
130: fixing plate fixing hall
200: cast iron
300: spiral rebar
400: high strength concrete
500: reinforcement band
600: stud bolt
700: Settlement
500: coupler
1000: 1st stake
2000: 2nd stake

Claims (5)

In the pre-made stake in the factory,
An end fixing plate 100;
The main reinforcing bar 200 is fastened to the fixing plate 100 without tension;
A spiral reinforcing bar 300 surrounding the main reinforcing bar 200;
A high-strength concrete 400 that is cast so that the main reinforcing bar 200 and the spiral reinforcing bar 300 are buried therein;
A reinforcement band 500 that wraps around the outer circumferential surface of the high-strength concrete 400 end and is joined to the outer circumferential surface of the fixing plate 100;
Consisting of, including
When the first pile 1000 and the second pile 2000 are joined to each other by welding with the fixing plate 100 facing each other,
Since the reinforcing band 500 of the first pile 1000 and the reinforcing band 500 of the second pile 2000 are continuous,
It characterized in that the stress generated from the first pile 1000 is directly transferred to the reinforcing band 500 of the second pile 2000 through the reinforcing band 500 of the first pile 1000,
The main reinforcing bar (200) is characterized in that it is installed in the underground by the purchase method, unlike the PHC file installed in the ground by implementing the RC pile installed without tension,
In the fixing plate 100, a fixing hole insertion groove 110 is formed, and the main reinforcing bar 200 is fastened with a coupler 800 to the fixing hole 700 inserted into the fixing hole insertion groove 110,
The anchorage 700 is composed of an inclined head 730 and a male thread 710,
The fixing hole insertion groove 110 is formed with an inclined groove 130 corresponding to the head portion 730,
The main reinforcing bar 200 is formed with a male thread (210),
The head portion 730 is installed in close contact with the inclined groove 130 so as not to be exposed to the outer surface of the fixing plate 100, without cross-section defects,
The male thread 710 and the male thread 210 are respectively fastened to both ends of the coupler 800,
In the manufacturing process, the coupler 800 has a function of mounting and fixing the end portion of the main reinforcing bar 200 to the fixing plate 100, and a vertical view of the fixing plate 100, which is difficult to maintain due to the fastening of a plurality of main reinforcing bars 200 And it characterized in that it performs a function of adjusting the horizontal degree by the rotation of the coupler 800,
A fixing plate fixing hole 130 is formed in the fixing plate 100,
Wherein the fixing hole insertion groove 110 is formed inward as much as the concrete coating thickness on the outer circumferential surface of the fixing plate 100, the fixing plate fixing hole 130 is not adjacent to the fixing hole insertion groove 110, but the fixing High-performance precast RC pile, characterized in that formed on the outer circumferential surface of the plate (100) regardless of the concrete coating thickness.
delete delete To produce the high-performance precast RC pile of claim 1,
(1) a main rebar thread processing step of forming a thread at the end of the main rebar 200;
(2) a rebar assembly completion step of joining the spiral reinforcing bar 300 to the main reinforcing bar 200;
(3) a joint reinforcement step of joining the reinforcing band 500 and the stud bolt 600 to the fixing plate 100;
(4) a reinforcing bar assembly step of fastening the main reinforcing bar 200 to the fixing plate 100 using the fixing tool 700 and the coupler 800;
(5) the installation step of the formwork fixing the fixing plate fixing hole 130 and the formwork of the fixing plate 100 installed at the end of the reinforcing bar assembly;
(6) placing a high-strength concrete to pour the high-strength concrete 400 inside the formwork;
(7) a centrifugal molding step of rotating the assembly of the fixing plate 100 and the formwork;
(8) steam curing step of curing the high-strength concrete 400 by applying steam;
Method of producing a high-performance precast RC pile characterized in that it comprises a.
In claim 4,
The (5) formwork installation step is a method for producing a high-performance precast RC pile, characterized in that a spacer is installed in the formwork and the rebar assembly is installed so as to maintain a covering thickness.

Images