KR102559018B1 - PHC Pile with Impact Reduction Performance - Google Patents

Abstract

An object of the present invention is a PHC pile having an impact dispersion function.
Specifically, the pile body 100 has a circular column shape and is formed of a concrete material; It is disposed on the pile body and includes a PC steel material 200 formed in plurality.

Description

PHC pile with impact dispersion function {PHC Pile with Impact Reduction Performance}

An object of the present invention is a PHC pile having an impact dispersion function.

Patent Inventions 001 to 004 present prior inventions in the related art to which the present invention has led.

Patent Document 001 relates to a composite pile formed by integrally connecting a PHC pile and a steel pipe, and more particularly, prevents damage due to stress concentration caused by a steel pipe being directly placed on the upper end of the PHC pile and a simple bolt joint. It relates to a composite pile having excellent workability by combining the PHC pile and the steel pipe. A composite pile composed of a PHC pile and a steel pipe connected using a bolt-on coupling member according to a preferred embodiment of the present invention is a hollow formed along the longitudinal axis in the center of the cross section and a PC nut embedded along the circumferential direction so as to be exposed to the end PHC pile; It is composed of a circular steel plate with bolt holes drilled at regular intervals in the circumferential direction and bolted to the top of the PHC pile, a connecting steel pipe whose lower end is coupled to the upper surface of the lower steel plate, and an upper steel plate in which the lower surface is coupled to the upper end of the connecting steel pipe. A coupling member composed of a joint steel pipe having first bolt holes formed at regular intervals in the circumferential direction and coupled to the upper surface of the upper steel plate to have the same longitudinal axis as the connecting steel pipe; A steel pipe pile having the same inner diameter as the outer diameter of the jointed steel pipe and having a second bolt hole formed at a corresponding position of the first bolt hole of the jointed steel pipe to be bolted to the jointed steel pipe of the coupling member.

The synthetic PHC pile for retaining wall according to Patent Document 002 is a PHC pile used for retaining wall construction, a PHC pile body in which a plurality of PC steel wires are embedded and a hollow part extending along the longitudinal direction is formed; A hollow concrete part formed by pouring concrete into the hollow part; And order holes formed to communicate with the hollow part at predetermined intervals along the longitudinal direction of the PHC pile body on one side of the PHC pile body receiving earth pressure; can include In the synthetic PHC pile for a retaining wall of the present invention, in the process of constructing the retaining wall, the concrete poured into the hollow part of the PHC pile body is discharged to the outer surface of the PHC pile body through a water order hole to form a water order structure. Because of this, the strength of the retaining wall can be improved. In addition, the composite PHC pile for retaining walls of the present invention can improve the rigidity of the PHC pile itself by filling the hollow part of the PHC pile with the reinforcing bar assembly and concrete.

The PHC pile according to Patent Document 003 has sufficient strength to withstand the compressive force and horizontal force, and can prevent the pile from being destroyed by earthquakes and horizontal loads. In order to achieve the above object, the present invention is a body including a hole in which a cross section perpendicular to the longitudinal direction is formed in a ring shape in the PHC pile and an empty space is formed in the center; and a PC steel wire disposed between an outer surface of the main body and an inner surface of the hole of the main body, and at least a portion of the main body may be formed of reinforcing fibers. The PHC pile according to an embodiment of the present invention has sufficient strength to withstand the compressive force and horizontal force, and can prevent the pile from being destroyed by earthquake and horizontal load. In addition, it is possible to prevent damage to piles during transportation, use or driving.

The PHC pile for a retaining wall according to Patent Document 004 relates to a PHC pile used in the construction of a retaining wall, which includes a pile body in which a plurality of PC steel wires are embedded, an insert nut member installed to be embedded in concrete constituting the pile body so that a nut hole is exposed on the surface of the pile body, and an insert nut member connected to the insert nut member and installed to be embedded in the concrete together with the insert nut member, and a pulling force acting on the insert nut member after construction of the PHC pile. and an insert reinforcing member supporting the insert nut member to resist against. In the PHC pile for a retaining wall according to an embodiment of the present invention, a furring strip or a furring bracket can be installed very easily using an insert nut member embedded in a plurality of PHC piles forming the retaining wall, and the insert reinforcing member provided on the nut member can reinforce the insert nut member to firmly and stably support the furring strip or furring bracket. In addition, since the PHC pile for earth retaining wall according to the embodiment of the present invention has a structure in which the insert reinforcing member is connected to the insert nut member and then embedded in the concrete constituting the pile body, the bonding force between the insert nut member and the pile body can be further improved to prevent the insert nut member from being abnormally pulled out from the pile body.

KR 10-2019-0048500 A (Public date May 09, 2019) KR 10-2173079 B1 (registration date October 27, 2020) KR 10-2020-0112194 A (Public date October 05, 2020) KR 10-2351779 B1 (registration date January 12, 2022)

An object of the present invention is a PHC pile having an impact dispersion function.

The present invention relates to a PHC pile having an impact dissipation function, and specifically, a pile body 100 having a circular column shape and made of concrete material; and a PC steel material 200 disposed on the pile body and formed in plurality. It includes.

The present invention is an invention for a PHC pile having an impact dissipation function, and in the above-described invention, the pile body includes a multi-layered concrete material formed in stages from the outside to the inside of the cross section.

The present invention relates to a PHC pile having an impact dispersion function, and in the above-described invention, a geotextile layer 110 is disposed between the concrete layers of the pile body.

The present invention is an invention for a PHC pile having an impact dispersing function, and in the above-described invention, the PC steel is formed spaced apart at equal intervals in the circumferential direction inside the pile body, and is tensioned to the end of the pile body. It includes being fixed.

The present invention is an invention for a PHC pile having an impact dissipation function, and in the above-described invention, a binding bracket 400 for connection with a neighboring pile body is formed at an end of the pile body.

The present invention relates to a PHC pile having an impact dissipation function, and during construction, it is possible to obtain an effect of preventing cracks and damage of the pile body by effectively distributing/absorbing shock waves according to pile driving.

In addition, when fastening the binding bracket for binding between piles of the present invention, binding can be easily performed through a one-touch coupler, so that effects such as work efficiency and construction convenience can be obtained.

1 is a step-by-step cross-sectional view of the pile body of the present invention.
Figure 2 is an embodiment of the PHC pile construction of the present invention.
Figure 3 is a combined perspective view of the binding bracket and one-touch coupler of the present invention.

Hereinafter, the most preferred embodiments of the present invention will be described in detail in order to explain the present invention in detail to the extent that those skilled in the art can easily practice the present invention.

Numbers cited in the examples below are not limited to the referenced subject and can be applied to all examples. An object that exhibits the same purpose and effect as the configuration presented in the embodiment corresponds to an equivalent replacement object. The high-level concept presented in the examples includes sub-concept objects that are not described.

(Example 1-1) The present invention is an invention for a PHC pile having an impact dissipation function, and specifically, a pile body 100 having a circular column shape and made of a concrete material; It is disposed on the pile body and formed in plurality. It includes a PC steel material 200.

(Example 1-2) The present invention relates to a PHC pile having an impact dispersion function, and in Example 1-1, a hollow part 300 is formed in the pile body.

(Embodiment 1-3) The present invention relates to a PHC pile having an impact dispersion function, and in Embodiment 1-2, geotextile 310: is disposed in the hollow part.

(Example 1-4) The present invention is an invention for a PHC pile having an impact dispersion function, In Examples 1-2 to 1-3, the hollow portion includes a reinforcing bar 320; and a filling material 330; including being formed.

The present invention (Example 1-1) aims at forming a PHC pile having an impact dissipation function.

In general, piles are installed in the ground to secure sufficient bearing capacity from the ground for loads generated by upper structures such as bridges and structures, and the load generated by the upper structure is supported by the bearing capacity of the ground at the tip of the pile and the frictional force between the pile and the surrounding ground.

These piles are mainly used depending on the material used, such as steel pipe piles, composite piles, and PHC piles.

Among them, the PHC pile is manufactured using centrifugal force by the pre-tension method, and is the most popular pile because of its excellent economic feasibility.

In addition, the PHC pile has a high risk of cracking and damage to the pile body during driving for ground penetration, and accordingly, it is difficult to secure reliability in the safety of the upper construction structure during long-term use.

The present invention is intended to fundamentally solve the structural problem of the conventional PHC pile, and specifically forms a pile body made of concrete material having a circular column shape.

In addition, a plurality of PC steel materials are formed in the pile body. When the PHC pile is manufactured, a plurality of PC steel wires are placed in the PHC pile manufacturing device before concrete pouring, and reinforcing bars are placed around the pile. After forming the formwork, concrete is poured, and the PHC pile is finally completed through formwork rotation.

Through this manufacturing operation, a hollow part may be formed in the pile body.

Geotextiles may be formed inside the hollow part, which may play a role of resisting horizontal deformation by absorbing shock waves according to external forces during driving and operation during future PHC pile installation and geotextile tension.

To this end, the geotextile is placed in the form of a wire or band with the PC steel before concrete placement, and improves the bending resistance performance of the PHC pile through tension with the PC steel.

In another embodiment, reinforcing bars and fillers may be additionally formed on the inner surface of the hollow part.

This is to improve the pile endurance and bending resistance performance by reinforcing the core by filling the hollow part of the PHC pile.

The reinforcing bar and filler may be applied to the site after pre-construction at the factory, or may be applied in the form of field construction after inserting the PHC pile into the ground at the site.

(Example 2-1) The present invention relates to a PHC pile having an impact dispersion function, and in Example 1-1, the pile body is formed of multi-layered concrete material step by step from the outside to the inside of the cross section.

(Example 2-2) The present invention is an invention for a PHC pile having an impact dispersion function, In Example 2-1, the stepwise outer layer concrete of the pile body includes higher strength than the inner layer concrete.

(Example 2-3) The present invention relates to a PHC pile having an impact dispersion function, In Example 2-1, the stepwise inner layer concrete of the pile body includes higher strength than the outer layer concrete.

(Example 2-4) The present invention is an invention for a PHC pile having an impact dispersion function, In Example 2-3, the innermost concrete of the pile body includes ultra-high strength concrete.

(Example 2-5) The present invention is an invention for a PHC pile having an impact dispersion function, In Examples 2-1 to 2-4, the outermost concrete of the pile body includes polymer concrete.

The present invention (Examples 2-1 to 2-5) embodies the configuration of the pile body.

In order to form the PHC pile having an impact dispersing function of the present invention, the pile body may be formed of different multi-layered concrete materials in stages from the outside to the inside of the cross section.

This is to dissipate the vibration waves according to the impact transmitted to the PHC pile by driving or the like through the PHC pile itself, and to pass through a medium made of different materials so that the vibration waves are gradually dissipated and dispersed.

As an example for this purpose, the concrete located in the stepwise outer layer of the pile body may be made of higher-strength concrete than the concrete located in the inner layer.

In general, the compressive strength of concrete used for PHC piles is 800kg/cm2 or more, so high-strength concrete is used.

In addition, conversely, the concrete located in the stepwise inner layer of the pile body may be made of higher strength concrete than the concrete located in the outer layer.

Here, the innermost concrete of the pile body may be formed of ultra-high strength concrete, for example, concrete having a compressive strength of 1,000 kg/cm 2 or more may be applied.

In addition, the outermost concrete of the pile body can be applied with polymer concrete. The polymer concrete includes polymer impregnated concrete (PIC) impregnated with a liquid polymer in cement concrete voids, and polymer in an emulsion state. Polymer cement concrete (PMC) is used as a binder together with cement.

Such polymer concrete has excellent compressive strength, good waterproofness and watertightness, so it forms the outside of the PHC pile body, and it can improve the problem of reducing the lifespan of the PHC pile, such as the inflow of moisture into the cracks of the conventional PHC pile and causing corrosion.

(Example 3-1) The present invention relates to a PHC pile having an impact dispersion function, and in Example 2-1, a geotextile layer 110 is disposed between the concrete layers of the pile body.

(Example 3-2) The present invention relates to a PHC pile having an impact dispersion function, In Example 3-1, the geotextile includes geotextile.

(Example 3-3) The present invention relates to a PHC pile having an impact dispersion function, In Example 3-1, the geotextile includes a geogrid.

(Example 3-4) The present invention is an invention for a PHC pile having an impact dispersion function, In Example 3-1, the geotextile includes a composite fiber.

(Example 3-5) The present invention relates to a PHC pile having an impact dispersion function, In Examples 3-4, the composite fiber includes a combination of carbon fiber and glass fiber.

The present invention (Examples 3-1 to 3-5) embodies the shape of the geotextile layer formed on the pile body.

One or more geotextile layers may be disposed between the graded concrete layers of the pile body.

Through the arrangement of the geotextile layer, a heterogeneous material layer is formed on the step-by-step concrete layer of the pile body, and through this, the effect of dissipating the vibration wave due to the impact transmitted to the PHC pile by driving in the previous description through the PHC pile itself can be maximized.

Here, the geotextile material used here can be polyamide with high wear resistance, polypropylene (PP) and polyester (PE), PVC, etc. that are light and non-absorbent, and glass fiber, carbon fiber, and aramid fiber can also be used, and it is preferable to select them according to the site conditions and apply them alone or in combination.

In order to position the geotextile between the pile bodies, that is, between the graded concrete layers, the geotextile may be applied in the form of a geotextile.

It is made of a sheet by weaving geosynthetics in a weft-warp yarn, and it is placed between the concrete layers in stages, and it can realize the effect of substantially canceling the propagation of the shock vibration wave into the inside of the pile body due to the driving.

In another embodiment, the geotextile may be placed in the pile body, that is, between the concrete layers in stages, and formed integrally through concrete curing at the same time, so that the geogrid shape of the lattice capable of concrete flow during pouring may be applied.

In another embodiment, the geotextile is a composite fiber, and a plurality of geotextiles may be applied in combination instead of a single material, in order to utilize the advantages of various geotextile materials in a complex manner.

As an example of this, the composite fiber may be applied by combining carbon fiber and glass fiber. The carbon fiber has the advantage of high tensile strength, but has the disadvantage of being broken even with small deformation, and the glass fiber has low tensile strength. However, it is excellent in ductility and can secure large deformability. By combining these fiber characteristics, composite fibers can be manufactured and applied to resist deformation due to external force of the PHC pile.

(Example 4-1) The present invention is an invention for a PHC pile having an impact dispersion function, and in Example 1-1, the PC steel materials are formed spaced apart at equal intervals in the circumferential direction inside the pile body, and are tensioned and fixed to the end of the pile body.

(Example 4-2) The present invention relates to a PHC pile having an impact dispersion function, In Example 4-1, the PC steel material includes a steel wire.

(Example 4-3) The present invention relates to a PHC pile having an impact dispersion function, In Example 4-1, the PC steel material includes a steel bar.

(Example 4-4) The present invention is an invention for a PHC pile having an impact dispersion function, In Example 4-1, the PC steel materials include those of stranded wire.

(Example 4-5) The present invention is an invention for a PHC pile having an impact dispersion function, In Example 4-1, the PC steel includes a steel band.

(Example 4-6) The present invention is an invention for a PHC pile having an impact dispersion function, In Examples 4-1 to 4-5, the PC steel includes high tensile strength steel.

(Example 4-7) The present invention is an invention for a PHC pile having an impact dispersion function, In 4-1 to 4-5, the PC steel materials include those of deformed steel materials.

The present invention (Examples 4-1 to 4-7) embodies the shape of PC steel.

The PC steel used in the PHC pile uses special PC steel to prevent the reduction in tension due to the high temperature that occurs during the manufacture of normal PHC piles.

The characteristics of these PC steels are high design bearing capacity, high resistance to driving, and high resistance to bending occurring during use.

The PC steel is formed inside the pile body at equal intervals in the circumferential direction, applied in a tensioned state to the inside where the pile body is to be formed before concrete curing, and fixed at the end of the pile body.

The PC steel can be used in the form of a normal steel wire, and can be in the form of a steel bar, in the form of a strand that can be re-tensioned by applying an end wedge, or by applying a steel band to improve tension performance. It can be applied by changing the shape of the tension member.

Additionally, in order to improve the performance of PC steel of the same volume, the material of PC steel may be high-strength steel, or it may be limited to a heterogeneous shape to improve the bonding performance with concrete of the pile body.

(Example 5-1) The present invention relates to a PHC pile having an impact dissipation function, and in Example 1-1, a binding bracket 400 for connection with a neighboring pile body is formed at an end of the pile body.

(Example 5-2) The present invention relates to a PHC pile having an impact dispersion function, In Example 5-1, the binding bracket includes a first binding bracket 410 formed at the upper end of the pile body located at the lower part; and a second binding bracket 420 formed at the lower end of the pile body located at the upper part. And a one-touch coupler 500 for binding the first binding bracket and the second binding bracket.

(Example 5-3) The present invention relates to a PHC pile having an impact dispersion function, In Example 5-2, the first binding bracket has a first screw thread 411 in a forward direction from the top to the bottom on the outer diameter, and a second screw thread 421 in the reverse direction from the bottom to the top on the outer diameter of the second binding bracket, and a third screw thread 511 corresponding to the first screw thread on the inner diameter of the one-touch coupler; and a fourth screw thread 521 corresponding to the second screw thread.

(Example 5-4) The present invention relates to a PHC pile having an impact dispersion function, In Example 5-3, the first and second screw threads include those formed with a partial length in the circumferential direction of the binding bracket.

(Example 5-5) The present invention is an invention for a PHC pile having an impact dispersion function, In Example 5-3, at least one wedge portion is formed at one end of the first and second screw threads.

(Example 5-6) The present invention is an invention for a PHC pile having an impact dispersion function, In Example 5-2, one or more fastening grooves 530 formed outside the one-touch coupler; and a one-touch coupler rotation tool 540 fastened to the fastening groove during construction and binding the first coupling bracket and the second coupling bracket by rotating the one-touch coupler in a circumferential direction.

The present invention (Examples 5-1 to 5-6) embodies the configuration of the binding bracket formed between PHC piles connected up and down.

The PHC pile is manufactured in a factory, transported and installed to a construction site in the form of a unit length, and it is necessary to increase the penetration depth of the PHC pile according to the size of the construction structure. Therefore, the PHC pile must be serialized in the vertical direction. Normally, the continuation of the PHC pile is performed by welding the end support plate located at the top of the pre-installed PHC pile and the tip of the PHC pile to be installed later, or by inserting / combining a separate bracket device and mutual bolting.

These welding and bolting operations depend on the reliability of the connection part depending on the skill level of the construction worker, and will have a huge impact on the integrity of the structure, such as support performance and bending resistance performance during service in the future.

Therefore, a separate device is required to improve the reliability and uniformity of the coupling between PHC piles, and in the present invention, a binding bracket is formed at the end of the pile body to connect with upper and lower neighboring pile bodies.

The binding bracket includes a first binding bracket formed at the top of the pile body of the PHC pile located at the bottom, a second binding bracket formed at the bottom, that is, the tip, of the pile body of the PHC pile located at the top, and the first binding bracket. And a one-touch coupler for binding the second binding bracket.

The first binding bracket has a first screw thread in a forward direction from the top to the bottom on the outer diameter, and a second screw thread in the reverse direction from the bottom to the top on the outer diameter of the second binding bracket is formed on the inner diameter of the one-touch coupler. The third screw thread corresponding to the first screw thread and the fourth screw thread corresponding to the second screw thread are coupled.

This coupling principle is the principle of a two-way screw thread coupler, and the directions of the threads on both sides of the coupler are processed differently (the right-hand thread and the left-hand thread are symmetrical) based on the center of the coupler.

When the double-headed thread is processed, when the coupler is rotated and tightened, the first and second binding brackets located on both sides are tightened while getting closer to each other, so that they can be easily fastened, and finally the PHC piles can be integrated in close contact with each other. Can be.

The first and second screw threads may be formed as part of a length of the coupling bracket in a circumferential direction. This is to ensure reliable fastening performance in a short time and easy workability, since the longer the screw thread is formed, the greater the risk of problems such as coupling errors.

Therefore, by forming a thread with a partial length in the circumferential direction, it is possible to easily proceed with the fastening operation of the one-touch coupler.

In addition, one or more wedges may be formed at one end of the first and second screw threads in order to maximize the binding effect by the one-touch coupler.

In addition, by forming wedges corresponding to the third screw thread and the fourth screw thread on the inner diameter of the one-touch coupler, the reliability of future loosening prevention and binding is improved through coupling between wedges in the binding finishing step, and the operator can measure the degree of binding between PHC files.

For this binding operation, a fastening groove into which a tool capable of easily rotating the one-touch coupler is coupled is formed on the outer diameter of the one-touch coupler, and the one-touch coupler rotation tool is inserted into the fastening groove and rotated in the rotational direction. The operator can easily and quickly perform the binding operation.

100: pile body 110: geotextile layer
200: PC steel
300: hollow part 310: geotextile
320: reinforcement 330: filler
400: binding bracket 410: first binding bracket
411: first thread 420: second binding bracket
421: second thread
500: one-touch coupler 511: third thread
521: fourth thread 530: fastening groove
540: one-touch coupler rotation tool

Claims (5)

In the PHC pile having an impact dispersion function,
Pile body 100, which has a circular column shape and is made of concrete material;
It is disposed on the pile body 100, and PC steel 200 formed in plurality; includes,
The pile body 100 includes one formed of multi-layered concrete material step by step from the outside to the inside of the cross section,
A geotextile layer 110 is disposed between the step-by-step concrete layers of the pile body 100,
The step-by-step inner layer concrete of the pile body 100 includes higher strength than the outer layer concrete,
The outermost concrete of the pile body 100 includes polymer concrete,
The geotextile of the geotextile layer 110 is a geotextile.
delete delete The method of claim 1,
The PC steel material 200 is formed spaced apart at equal intervals in the circumferential direction inside the pile body 100, and has an impact dispersing function including being tensioned and fixed to the end of the pile body 100. PHC pile.
The method of claim 1,
A PHC pile having an impact dissipation function including a coupling bracket 400 for connection with a neighboring pile body 100 at an end of the pile body 100.