KR100784650B1 - Structure of concrete pile cap assembly - Google Patents

Abstract

A concrete pile cap assembly structure is provided to support dead weight of vertical reinforcing bars and dead weight of concrete mortar by inserting a cut part of a concrete mortar support disk to the hollow of a concrete pile flexibly and welding a substitute member for welding to vertical reinforcing bars firmly, and to support a concrete pile cap structure and to enlarge an input space of concrete mortar by forming a hanging part with a steel bar, not a steel plate and welding with vertical reinforcing bars. A concrete pile cap assembly structure is formed by inserting a cut part(142) of a concrete mortar support disk(14) to the hollow of a concrete pile flexibly, and installing a substitute member for welding at the bottom of the concrete mortar support disk, wherein the substitute member for welding is welded and fixed to the vertical reinforcing bars firmly to support the concrete mortar support disk, thereby to support dead weight of vertical reinforcing bars and concrete mortar. In addition, a hanging part(16b) suspended on the front end of the concrete pile is formed with a steel bar instead of a steel plate to reinforce the welding of the vertical reinforcing bar and the steel bar and to secure an input space for concrete mortar.

Description

Structure of concrete pile cap assembly

The present invention relates to a concrete pile cap assembly structure that serves to integrate the coupling portion of the hooking foundation and the concrete pile into one body.

The load of the superstructure is transferred to the concrete pile through the hooking foundation. The transferred upper load is a structure supported by the concrete pile installed on the ground.

The hooking base is a horizontal member and the concrete pile is a vertical member.

However, the contact area between the horizontal member and the vertical member is very small.

If the horizontal member and the vertical member are not integrated into one body, the upper load is not properly transmitted to the vertical member through the horizontal member. When the upper load is not transmitted to the vertical member, the horizontal member should be in charge of it, but the horizontal member is not formed as firmly as the vertical member, so there is a risk of destruction.

1A and 1B are known as a conventional concrete pile cap assembly 10a.

1A and 1B, the concrete pile cap assembly 10a serves to connect and fix the hooking foundation and the concrete pile 20. As shown in FIG.

The concrete pile cap assembly 10a serves to transfer the load of the superstructure to the concrete pile 20 through the hooking foundation.

The concrete pile 20 and the hooking foundation are not constructed at the same time. First, the concrete pile 20 is vertically driven to the ground, and then the hooking foundation is constructed on the concrete pile 20.

As such, since the concrete pile 20 and the hooking foundation are not constructed at the same time, it is most important to integrate the two members.

If the two members are not integrated, the load of the upper structure is not transmitted to the concrete pile 20, and the hooking foundation should take charge of this. This puts a strain on the hooking foundation. In severe cases, the hooping foundation leads to fracture.

The concrete pile 20 is a vertical member and the hooking base is a horizontal member.

The joint where the concrete pile 20 and the hooking base are in contact has a very small contact area.

The concrete pile cap assembly 10a serves as a medium between the concrete pile 20 and the hooking foundation to secure the joint.

In other words, while the concrete pile cap assembly 10a is inserted into the concrete pile hollow part 22 and serves to form a body with the concrete pile 20, at the same time serves to form a body with the hooking base.

The concrete pile cap assembly 10a will be described with reference to the concrete pile 20 and the hooking foundation.

1) Configuration of the Concrete Pile Cap Assembly 10a

 end. Vertical Rebar (12)

The vertical reinforcing bar 12 serves to integrate the concrete pile 20 and the hooking foundation. The vertical reinforcement 12 is inserted into the concrete pile hollow 22, and at the same time connected to the main reinforcing bar of the futing foundation.

If the vertical reinforcing bars 12 can be fixed to the hollow portion 22 of the concrete pile by self-supporting, there is no need for a peripheral configuration for fixing the vertical reinforcing bars 12.

However, since the vertical reinforcing bar 12 can not be fixed to the hollow portion 22 of the concrete pile by self-supporting, only a peripheral configuration for fixing the vertical reinforcing bar 12 is necessary.

Peripheral configuration for this is the concrete mortar 18, the concrete mortar support disk 14, the iron plate straddling portion 16a that spans the concrete pile tip 24 and the like.

The vertical reinforcing bar 12 penetrates through the concrete mortar support disc 14 and the iron plate holding part 16a, and is fixed by welding.

In other words, the vertical reinforcing bar 12 is supported by the concrete mortar support disc 14 and the iron plate latch 16a.

The vertical reinforcement 12 rises above the concrete pile tip 24. The vertical reinforcing bar 12 rising above the tip 24 is firmly connected to the main reinforcing bar of the futing foundation.

 I. Concrete mortar supporting disc (14) and cutout (142)

  A) Concrete mortar supporting disc (14)

Concrete mortar support disk 14 'serves to support the vertical reinforcing bars 12 and at the same time serves as a vessel containing the concrete mortar 18, and supports the weight of the concrete mortar 18.

  B) incision (142)

The concrete mortar support disk 14 is formed with a cutout 142.

In order to facilitate the insertion into the concrete pile hollow (22).

The hollow part 22 of the concrete pile is not a garden. The hollow portion 22 is not formed in a constant circle. This can be found in the manufacturing process of the concrete pile 20.

Most of the concrete piles 20 currently in use are hollow cylindrical piles produced using centrifugal force.

Since the circular mold is manufactured by rotating at high speed, the concrete mortar is collected by the centrifugal force to the main surface of the mold, and the hollow is naturally formed in the center portion.

In the process of rotating at high speed, the aggregate having a large specific gravity is collected toward the mold main surface and the small specific gravity is collected at the surface of the hollow part. The fine material of impurities collects in the hollow part, and after the water evaporates, the fine material of impurity remains on the surface of the hollow part. This is called latency.

Latency generated on the surface of the hollow portion is a cause for preventing the hollow portion from becoming a garden.

Another reason is that the concrete pile produced by centrifugal force has no mold in the hollow part, so that the force of concrete mortar flows down in the direction of gravity during curing of the uncured state. In the state where the centrifugal force is applied, even if the hollow part is in the garden state, the gravity is acted once in the state where the centrifugal force is not applied, and the garden is gradually distorted in the uncured state.

If the latencies are overlapped, the distortion of the garden becomes larger.

However, this phenomenon does not occur because the outer circumferential surface of the concrete pile is cured while in contact with the mold.

Since the hollow part of the concrete pile is crushed out of the garden, it is almost impossible to insert the garden mortar supporting disc into the hollow part. In order to facilitate the insertion work, an incision is formed in the concrete mortar supporting disc.

By the way, the concrete mortar support disk 14 serves as a container for holding the concrete mortar 18 and at the same time serves to support the weight of the vertical reinforcing bars 12 and concrete mortar 18, the strength should be large.

In other words, the concrete mortar supporting disk 14 should have a thickness sufficient to support the weight of the vertical reinforcing bars 12 and the concrete mortar 18, and at the same time satisfy the requirement that the concrete mortar supporting disk be easily inserted into the hollow part of the crushed shape. .

Since the concrete mortar support disk 14 is welded with the vertical rebar 12, the material is a steel plate. Iron plate material is most sure to support the weight of the vertical reinforcement (12) and concrete mortar (18), but there is a problem that it is not easy to insert the hollow portion of the crushed shape.

However, simply forming the cutout 142 on the main surface of the concrete mortar support plate 14 does not facilitate the insertion immediately.

Even if the cutout 142 is formed, if the iron plate of the concrete mortar support plate 14 is thick, it is impossible to insert the hollow part 22 of the concrete pile. This is because a thick iron plate cannot flexibly respond to the crushed circle.

When the iron plate of the concrete mortar support plate 14 is thinned to be able to respond flexibly, a problem arises in welding the thin steel plate of the vertical reinforcement 12 and the concrete mortar support plate 14. Welding is to melt the vertical reinforcing bar 12 and the iron plate at a high temperature to form a body. If only one side melts and sticks, it will fall easily. It is unable to withstand the weight of the vertical reinforcing bars 12 and the weight of the concrete mortar 18.

The vertical reinforcing bars 12 should be melted and the iron plate of the concrete mortar supporting disc 14 should be melted.

Since the vertical reinforcing bars 12 are thick, there is no problem even if they melt. However, when the iron plate of the concrete mortar support plate 14 is melted, the iron plate is too thin to form holes.

When a hole is formed in the iron plate of the concrete mortar support plate 14, the concrete mortar 18 is leaked, thereby causing a problem in forming the concrete pile.

The iron plate of the concrete mortar supporting plate 14 must satisfy three requirements simultaneously.

Iii) have a thickness capable of supporting the weight of the vertical rebar 12 and the weight of the concrete mortar 18;

Ii) The incision 142 should be flexible enough to facilitate insertion into the hollow 22 of the concrete pile.

Ⅲ) No hole shall be formed in the steel plate due to welding of the vertical bars 12 and the steel plate of the concrete mortar supporting plate 14.

The concrete mortar support disc 14 of the conventional concrete pile cap assembly 10a as shown in FIG. 1 is a structure that cannot satisfy the above three requirements at the same time.

If the concrete mortar support disk 14 is not satisfied three requirements at the same time the problem is as follows.

   문제점 Problems when the concrete mortar supporting disk 14 supports the weight of the vertical reinforcing bar 12 and the weight of the concrete mortar 18

Since the steel plate of the concrete mortar support plate 14 is thick, welding between the vertical rebar 12 and the steel plate of the concrete mortar support plate 14 can be rigid, whereas the cutout 142 is not flexible. There is a problem in that it is virtually impossible to insert the concrete mortar support disc 14 into the concrete pile hollow 22.

   문제점 Problem of easy and flexible insertion of concrete mortar supporting disk 14 into concrete pile hollow part 22

Since the thickness of the iron plate of the concrete mortar support plate 14 is thin, the incision 142 is flexible and the insertion is flexible, while the vertical rebar 12 and the steel plate of the concrete mortar support plate 14 are welded to the iron plate. There is a problem that a hole is formed, and in order to prevent the hole from being formed in the steel plate, the welding is not hardened so that the concrete mortar supporting disc 14 withstands the weight of the vertical bar 12 and the weight of the concrete mortar 18. There is a problem that falls into the bottom of the concrete pile hollow (22).

 All. Iron plate hanger (16a)

The concrete pile cap assembly 10a is supported by the iron plate latch 16a.

The prior art iron plate latch 16a of FIG. 1 is made of iron plate. The vertical reinforcing bar 12 penetrates the iron plate fastening part 16a, and the vertical rebar 12 and the iron plate fastening part 16a are welded.

Since the steel plate latching portion 16a and the vertical reinforcing bar 12 are supported by each other by welding, the thickness of the iron plate should be thick to solidify the welding. If the thickness of the iron plate is thick, handling is inconvenient and uneconomical problem.

When the thickness of the steel sheet is thinner, the operation is easy and economical, but as described above, there is a problem in that the hole is formed in the steel plate, and there is a problem in that the welding is not rigid. If the welding of the iron plate striking portion (16a) is not strong, the concrete pile cap assembly (10a) is unable to withstand the weight of the vertical reinforcing bars 12 and the weight of the concrete mortar to fall into the bottom of the concrete pile hollow portion 22 occurs .

In addition, since the vertical reinforcing bar 12 penetrates the plate rest 16a, the input space S into which the concrete mortar 18 can be input is reduced. This results in longer working hours.

In addition, the iron plate straddling portion 16a hinders the input space S into which the concrete mortar 18 may be introduced. This is because the vertical reinforcing bar 12 penetrates the iron plate engaging portion 16a.

 la. Concrete mortar

The concrete mortar 18 is inserted into the concrete pile cap assembly 10a inserted into the concrete pile hollow 22 to serve to make the vertical reinforcement 12 and the concrete pile hollow 22 into one body.

The concrete mortar 18 is supported by the concrete mortar support disc 14 of the concrete pile cap assembly 10a.

If the concrete pile cap assembly 10a cannot support the concrete mortar 18 or leaks from the concrete pile cap assembly 10a, the concrete pile cap assembly 10a cannot form a body with the concrete pile 20 and the hooking foundation, thereby increasing the load of the upper structure. There is a problem that the concrete pile 20 can not support.

2) the mediating role of the concrete pile cap assembly 10a

The concrete pile cap assembly 10a serves to form a body with the concrete pile 20 and the hooking foundation. To allow the concrete pile 20 to support the load of the superstructure transferred through the hooking foundation.

 end. Located between the concrete pile 20 and the hooking foundation

The concrete pile cap assembly 10a is positioned between the concrete pile 20 and the hooking foundation to transfer the load of the upper structure to the concrete pile 20 through the hooking foundation.

 I. Depth inserted into concrete pile hollow 22 of concrete pile cap assembly 10a

The depth to be inserted into the concrete pile hollow part 22 of the concrete pile cap assembly 10a is 40 to 60 cm.

 All. Length of vertical rebar 12 connected to the hooking foundation

The vertical reinforcing bar 12 rises 20-30 cm above the tip 24 of the concrete pile. The vertical reinforcing bars 12, 20-30 cm, are connected to the main reinforcing bars of the hooking foundation.

An object of the present invention is to install the welding substitute member on the lower part of the concrete mortar support disk while the cutting part of the concrete mortar support disk is inserted flexibly in the hollow part of the concrete pile and weld it firmly with the vertical reinforcement and concrete The mortar weight of the mortar ensures that the support plate of the concrete mortar is reliably supported.Replace the steel bars of the tip of the concrete pile with reinforcing bars or circular bars instead of the steel plate, and weld them with the vertical bars to ensure the concrete pile cap structure. There is another purpose to make it possible, and another purpose is to expand the input space of the concrete mortar by replacing the steel bars with steel bars or circular steel bars instead of steel plates.

In order to flexibly insert the cutout 142 of the concrete mortar support plate 14 into the hollow part 22 of the concrete pile, the iron plate of the concrete mortar support plate 14 may be thin.

If the thin steel plate and the vertical reinforcing bar 12 is welded, it is inevitable that a hole is formed in the thin iron plate.

The concrete mortar supporting disk 14 is a member supporting the self weight of the vertical reinforcing bar 12 and the self weight of the concrete mortar.

The present invention allows the concrete mortar support disc 14 to support the weight of the vertical reinforcing bars 12 and the weight of the concrete mortar 18 while the hollow part 22 of the concrete pile.

The flexible member is inserted as well as the welding member 15 is installed in the lower end of the concrete mortar support disk 14, the substitute member welded to the vertical reinforcement (12).

That is, the welding substitute member 15 is installed at the lower end of the concrete mortar supporting disc 14 having the cutout 142 formed therein to wrap the vertical reinforcing bars 12, and the vertical rebar 12 and the welding substitute member 15 are firmly installed. To be welded.

The welding substitute member 15 serves to support the concrete mortar supporting disk 14 while being firmly welded and fixed to the vertical rebar 12.

The welding substitute member 15 supports the weight of the vertical reinforcing bar 12 and the weight of the concrete mortar 18 to be supported by the concrete mortar supporting plate 14.

In addition, the present invention is a configuration in which the fastening portion that extends over the concrete pile tip 24 is replaced with a steel bar instead of the iron plate.

As described in the welding of the iron plate and the vertical reinforcing bars 12, the iron plate should be thick so that the welding does not cause a hole in the iron plate. This is inconvenient to handle and uneconomical. The thickness of the steel sheet should be thin for economical and easy handling.

But there is a problem with welding. In order to solve this problem, the present invention is a steel rod hooking portion (16b) configuration is replaced with a steel rod.

The welding of the vertical reinforcing bars 12 and the steel rods is not only rigid but also does not interfere with the introduction of the concrete mortar 18. The input space S of the concrete mortar 18 can be enlarged.

The present invention is installed on the lower end of the concrete mortar support disk in the form of wrapping the vertical reinforcing bar and welded it with the vertical rebar, so that it is effective to prevent the formation of holes in the steel plate of the concrete mortar support disk as well as the vertical rebar The welding substitute member has the effect of sharing the burden of the concrete mortar supporting disk which is dedicated to the weight of self and the weight of concrete mortar.

In addition, since the cladding portion over the concrete pile tip portion is formed by a steel rod cladding portion instead of the conventional steel sheet cladding portion, the space for injecting the concrete mortar into the concrete pile cap assembly structure is widened, and thus the concrete mortar is easily added and the work is efficient.

In addition, the steel bar fastening part welded directly to the vertical reinforcing bar does not generate holes such as deterioration of bearing capacity unlike the conventional steel plate fastening part due to welding, so the steel bar fastening part firmly and firmly supports the concrete pile cap assembly structure as compared to the steel plate fastening part. It is a useful invention.

Concrete mortar supporting plate 14 of the present invention is an iron plate material. An incision 142 is formed on the main surface of the concrete mortar supporting disk 14.

The concrete mortar supporting disk 14 is a member inserted into the hollow portion 22 of the concrete pile. Since the hollow part 22 of the concrete pile is a crushed circle rather than a garden, even if the cutout 142 is formed, it is not easy to insert.

The thicker the cutout 142 is, the more inflexible the insertion of the hollow part 22 becomes.

The thickness of the iron plate forming this rather than the incision 142 should be thinner.

If the thickness of the iron plate is thin, even if only one spot welded or do not bear the weight of the concrete mortar 18 and the weight of the vertical reinforcement (12) placed on it will not be welded.

In order to withstand the weight of the concrete mortar 18 and the weight of the vertical reinforcing bar 12, the incision 142 is flexible, and the thickness of the incision is inevitably caused by welding. .

In practice, such problems are common in construction sites.

It is most ideal if the hole is not formed by welding while having the flexibility of the cutout 142. However, flexibility and welding are inversely related, so it is most important to avoid welding directly with the steel plate. In order to avoid direct welding with an iron plate, in the present invention, the welding substitute member 15 is installed at the lower end of the concrete mortar supporting disc 14. Direct welding of the vertical reinforcing bar 12 and the welding substitute member 15, and not with the iron plate of the concrete mortar support plate (14). The welding substitute member 15 is made of steel bars or steel bars. Even if it is firmly welded with the vertical reinforcing bar 12, the hole is not formed by welding, regardless of its shape.

The welding substitute member 15 is a structure which supports the concrete mortar support disk 14.

The welding substitute member 15 shares the load acting on the concrete mortar support disk 14.

Fixing of the concrete mortar support disk 14 and the vertical rebar 12 is demonstrated.

Since the iron plate of the concrete mortar support plate 14 has to use a thin one, it is sufficient that the welding of the iron plate does not fall from the vertical reinforcing bars 12 while the cutout 142 is inserted into the hollow part 22. It is enough to weld slightly enough that two members are attached.

Alternatively, the welding substitute member 15 may be provided on the concrete mortar support disk 14.

In this case, the vertical reinforcing bars 12 and the concrete mortar supporting disk 14 are not welded.

Next, the steel bar fastening part 16b is demonstrated.

The steel bar fastening portion 16b provided at the concrete pile tip portion 24 is a member that divides into two regions.

One role is to support the full load of the concrete pile cap assembly structure 10b inserted into the concrete pile hollow 22.

Another role is to provide a space S for injecting the concrete mortar 18 into the concrete pile cap assembly structure 10b.

In the case of the iron plate hanger 16a as in the prior art, while the iron plate hanger 16a interferes with the concrete mortar input space S, the steel rod stopper 16b does not interfere with the input space S.

The shape of the steel bar hanging portion 16b is “a” shape 162 as shown in FIGS. 3a to d or a circular shape 163 as shown in FIGS. 2a to c. In the circular shape 163, a protrusion 164 is formed to span the concrete pile tip 24. The portion to be welded with the vertical reinforcing bar 12 is the vertical portion 162b in the "a" shape 162, the circular portion 166 (non-projection) in the circular shape 163.

Since the steel bar fastening portion 16b only needs to be firmly welded to the vertical reinforcing bar 12, the shape of the steel bar fastening portion 16b is sufficient to be a deformed steel bar or a circular steel bar, and the flat steel having similar strength is included here. .

The “a” shape 162 is firmly welded to each other in a state where the circular steel bars 165a surround the vertical reinforcing bars 12 from the outside. The vertical portion 162b of the “a” shape 162 is welded to the vertical rebar 12, and the horizontal portion 162a of the “a” shape 162 is welded to the circular steel bar 165a.

In the circular shape 163, a protrusion 164 is formed to span the concrete pile tip 24. The circular portion 166 (non-projection) and the vertical reinforcing bar 12 are firmly welded to each other.

Figure 1a perspective view of a conventional concrete pile cap assembly

1B is a cross-sectional view showing a state in which a conventional concrete pile cap assembly is inserted into a hollow portion of a concrete pile

Figure 2a perspective view of the concrete pile cap assembly structure of the present invention

2b is a plan view of a concrete pile cap assembly structure of the present invention

Figure 2c bottom view of the concrete pile cap assembly structure of the present invention

Figure 3a perspective view of another embodiment of the concrete pile cap assembly structure of the present invention

3B is a plan view of another embodiment of a concrete pile cap assembly structure of the present invention

Figure 3c Another embodiment bottom view of a concrete pile cap assembly structure of the present invention

3D is a cross-sectional view showing a state in which the concrete pile cap assembly structure of the present invention of FIG. 3A is inserted into the hollow portion of the concrete pile

<Description of the symbols for the main parts of the drawings>

10a; Concrete pile cap assembly (conventional)

10b; Concrete pile cap assembly structure (invention)

12; Vertical rebar

14; Concrete mortar supporting disc, 142; Incision,

15; Welding substitute member, 152; welding

16a; Iron plate hook (conventional), S; Concrete mortar input space

16b; Steel rod clasp (present invention), 162; "A" form, 162a; Horizontal portion 162b; Vertical portion, 163; Circular form, 164; Protrusion, 165a; Circular rods, 166; Circular portion (non-projection), 168; welding,

18; Concrete mortar

20; Concrete pile

22; Concrete pile hollow

24; Concrete pile tip

Claims (5)

delete In the concrete pile cap assembly having a vertical reinforcing bar 12, a concrete mortar support disc 14 having a cutout portion 142, and a hanging portion that extends over the concrete pile tip 24 The welding substitute member 15 is installed at the lower end of the concrete mortar supporting disk 14 in the form of enclosing the vertical reinforcing bar 12 and welded to the vertical reinforcing bar 12 firmly (152). The circular portion 163 of the circular shape 163 over the concrete pile tip portion 24 consists of a protrusion 164 and a circular portion 166, while the circular portion 166 and the vertical reinforcement in a state surrounding the vertical reinforcement 12 from the outside Concrete pile cap assembly structure characterized in that 12 is firmly welded 168. 3. The concrete pile cap assembly structure according to claim 2, wherein the hook portion of the circular shape 163 that extends over the concrete pile tip portion 24 is made of flat iron. 3. The hook portion of the “a” shaped shape 162 that extends over the concrete pile tip portion 24 is welded to each other with a circular steel bar 165a enclosing the vertical reinforcement 12 from the outside. The concrete pile cap assembly structure, characterized in that the vertical portion 162b of the ruler shape 162 is welded to the vertical reinforcement 12, and the horizontal portion 162a is welded to the circular steel bar 165a. 3. The concrete pile according to claim 2, wherein the welding substitute member 15 is installed on the upper end of the concrete mortar supporting disk 14 in the form of enclosing the vertical reinforcing bars 12 and welded thereto with the vertical reinforcing bars 12. Cap assembly structure

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