KR101700851B1 - Big helical pile - Google Patents

Abstract

The present invention relates to a big helical pile. The big helical pile comprises: a helix body having a lead angle of zero; a cutting blade formed on a leading edge of the helix body curved downwards; a cut soil cleaning blade formed on a trailing edge of the helix body curved upwards; a cutting guide blade disposed on an edge of a lower surface of the helix body; and a cut soil guide blade disposed on an edge of an upper surface of the helix body. A buckling load is not generated during a construction process even if applied to a small helical pile and a larger helical pile to accurately and vertically insert a pipe into the ground. Torque loss is minimized by an amount of buckling load not generated to allow construction by a small torque.

Description

Big helical file {Big helical pile}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a helical file, and more particularly, to a helical file, as well as a small helical file, as well as a large helical file, The helical file can be vertically and precisely penetrated, the helix file can be penetrated even with a small torque, and the cutting edge, which is formed by a downwardly curved cutting edge at the leading edge portion of the helix, And a trailing edge portion of the helix is provided with an upwardly curved soil gravel guide edge to effectively cut the ground. The helical cutting guide has an arc-shaped cutting guide blade on the lower surface of the helix, It is possible to provide a more accurate vertical Helical one big file so that it can be as intrusive; relates to (Big Helical Pile BH Pile).

In general, piles are introduced into the ground in the construction of a foundation supporting the load of a building or a civil structure. In the past, a method of striking a file by striking it and a method of press- Has been used.

However, as the conventional striking method and press-fitting method are pointed out to safety problems and environmental problems due to noise and vibration during construction, rotational indentation methods have been developed and used.

In the rotary indentation method, a helical anchor pile is used. The helical file includes a helical file body in the form of a pipe and a plurality of helixes formed on the outer circumferential surface of the helical file body.

In addition, the helical file body is coupled to a hydraulic rotary device installed at the front end of a boom of a backhoe, without using a large equipment such as an auger drill machine.

Therefore, the height of the equipment for rotating the helical file can not be increased indefinitely, so that the length of the helical file is set to about 3 m. If the required penetration depth is deeper than the helical file, one or more shafts Anchor file (a simple pipe-type file without helix) is connected and intruded.

A typical helical file construction method is performed through a helical file penetration step, a shaft file connection and penetration step, a grouting step, a head part cleaning step, and a dynamic test step. It is possible to shorten the air to 250m / day by the integrated construction of the pile. It is excellent in the construction quality, and it is possible to improve the stability of the construction and the environment by the non-dusting, In addition to advantages such as civil appeal and dispute settlement, it is possible to minimize the disturbance of ground during construction of soft ground, so that it is possible to construct even at an inclined angle.

However, the conventional helical file construction method has various problems.

First, the tip of the helical file body of the helical file is sloped or the conical head with the bottom is joined to facilitate digging into the ground. However, if it is necessary to pass through the rock during the construction process, There is a problem that this becomes impossible.

Second, helical file body and shaft anchor file of helical file use the same diameter pie. To connect helical file and shaft anchor file, connect the top of helical file body and the connecting sleeve at the bottom of shaft anchor file. When connecting several shaft anchor piles, it is necessary to connect the shaft anchor pile to the shaft anchor pile. In order to connect the shaft anchor pile to the shaft anchor pile, The connecting sleeve is inserted into the lower end of the shaft anchor pile and the connecting pin is inserted through the connecting sleeve and the upper and lower shaft anchor piles so that when the large torque is applied at the time of construction, There is a problem that the connection part of the anchor pile is damaged and construction is delayed.

Therefore, it is possible to construct even when it is necessary to pass through the rock bed during construction, to minimize the boring load and to prevent the large torque from being applied, and to develop the technology that enables construction with economical construction .

As a prior art in response to such a demand, Korean Patent No. 1552139 (registered as 2015.09.04) "helical file" (hereinafter referred to as "prior art") is disclosed.

The above prior art can minimize the resistance of the cut soil when penetrating into the ground by forming cutouts in the outer periphery of a plurality of helixes provided in the helical file and improve the cutting performance of the ground by providing cutting edges at the cut- , A crushing crown having an outer circumferential cutting tip made of a material having excellent cutting power at the lower end of the helical file and a crushing crown having a cutting tip at the lower end is pierced so that the crushing crown can perforate the ground before the ground cutting by the helix, It is possible to construct even when the rock is to be passed through the rock during construction, and it is possible to reduce the burden on the cutting of the helix, so that the construction of the helical pile can be performed more quickly, It is possible to construct even with a rotating device, thereby enabling economical construction.

However, in the prior art, since the helix is formed in a spiral shape having a predetermined lead angle, the earth pressure generated in the process of cutting the ground acts on the helical surface of the helix, The buckling phenomenon occurs in the helical file body as a result of the buckling load, and as a result, the helical file is not precisely penetrated vertically. As a result, in rotating the helical file by the hydraulic rotating device, A large torque is required.

Such a problem is more apparent in the case of a large helical file having a large outer diameter of the pipe constituting the helical file body and a large helical diameter.

Therefore, even when applied to a large helical file as well as a small helical file, the earth pressure generated in the penetration process does not act as a buckling load on the helical file body, so that the helical file can be accurately and vertically penetrated, It is required to develop a technique that allows a helical file to be intruded as a torque.

Korean Registered Patent No. 1552139 (Registered on April 5, 2014) "Helical File"

Therefore, it is an object of the present invention to provide a helicopter that can prevent a earth pressure generated in a penetration process from acting as a buckling load on a helical file body, even when applied to a large helical file as well as a small helical file, And to provide a big helical file that allows the helical file to be intruded even at low torque.

Another object of the present invention is to provide a cutting edge having a cutting edge that is downwardly curved and sharp at the leading edge portion of the helix and has a sharp edge at the trailing edge portion of the helix, And to provide a big helical file that effectively cuts the ground by providing a blade.

It is still another object of the present invention to provide a helical cutter which is provided with an arcuate cutting guide blade on the lower surface of a helix and has a cutting soil guide tooth on the top surface of the helix, .

According to an aspect of the present invention, there is provided a helical file main body comprising a circular pipe. A piercing head coupled to a lower end of the helical file body; A pair of helixes rotationally symmetrically joined to an outer circumferential surface of the helical file body above the perforation head; Wherein the piercing head includes a circular plate joined to a lower end of the helical file body, a coupling cylindrical portion joined to an upper surface of the circular plate to be inserted into a lower end of the helical file body, And a plurality of perforated blades formed at regular intervals on the lower surface of the circular plate, wherein the plurality of perforated blades are formed in a right triangle shape so that two orthogonal sides form upper and lower sides, And the upper side is welded to the lower surface of the disk by welding, and the pair of helixes are smaller than the semicircle and larger than 1/4 circle A cutting board main body having a circular arc surface and being installed horizontally, and a cutting edge formed on the leading edge of the cutting board main body and curved downwardly And a cutting gum arrangement blade formed upwardly on a trailing edge of the cutting plate complementary body, wherein the helix body has a lead angle of "0" and is perpendicular to the helical file body And a plurality of cutting guide teeth formed in an arc shape having an outer diameter equal to the outer diameter of the helix body are formed at the bottom edge of the helix main body when the helical main body is vertically erected, A plurality of cutting gravel-piece-like guiding blades formed in an arc shape having an outer diameter equal to the outer diameter of the helix body are formed on the upper surface edge of the helix body so as to protrude from the cutting grit- The protruding height of the large helical file can be reduced.

According to the big helical file of the present invention, the helical body having the lead angle of "0 " and the cutting edge formed downwardly curved at the leading edge of the helix body and the cutting grit comb-forming blade formed upwardly curved at the trailing edge of the helix body, And a cutting gravel-curving guide blade provided on an upper edge of the helix main body. Therefore, even when applied to a large helical file as well as a small helical file, the buckling load does not act during the construction process, So that the torque loss can be minimized as the buckling load is not generated, so that the construction can be performed even with a small torque.

1 to 5 show a preferred embodiment of a big helical file according to the present invention,
1 is a partially cutaway perspective view of a big helical file viewed from above,
2 is a partially cutaway perspective view of the big helical file viewed from below,
3 is a partially cut exploded perspective view of the big helical file viewed from above,
4 is a partial cutaway exploded perspective view of the big helical file viewed from below,
5 is a partially cutaway perspective view showing a shaft file used in connection with the big helical file of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a big helical file according to the present invention will be described in detail with reference to the preferred embodiments illustrated in the accompanying drawings.

The big helical file HP according to the present embodiment includes a helical file main body 100 formed of a circular pipe; A piercing head 200 coupled to a lower end of the helical file body 100; A pair of helixes 300 that are rotationally symmetrically joined to the outer circumferential surface of the helical file body 100 above the perforation head 200; .

The helical file main body 100 is provided with a connection head 110 for connecting a hydraulic rotary device (not shown) or a shaft file SP coupled to the boom of the backhoe.

The connection head 110 is formed of a circular pipe having an inner diameter corresponding to the outer diameter of the helical file body 100, and a plurality of connection pin holes 111 for receiving the connection pin 120 are formed.

The connection pin 120 may include a pin having a head larger than the inner diameter of the connection pin hole 111 and a pin or the like for preventing the pin from being disengaged from the connection pin hole 111, A connecting bolt 121 passing through the connecting pin hole 111 and a connecting nut 122 fastened to the projecting end of the connecting bolt 121.

Although the helical file body 100 is partially cut in the drawing, the length of the helical file body 100 may be 4 m, and the helical file body 100 may have a different length depending on the circumstances.

The piercing head 200 includes a circular plate 210 bonded to a lower end of the helical pile body 100 and a circular plate 210 coupled to the upper surface of the circular plate 210 and inserted into the lower end of the helical pile body 100 And a plurality of (six in the drawings) perforated blades 230 formed in a right triangle and joined to the lower surface of the circular plate 210 at equal angular intervals.

The disk 210 is composed of an iron plate having an outer diameter corresponding to the outer diameter of the helical file body 100 and is welded to the lower end of the helical file body 100 by welding.

The circular plate 210 is formed to have an outer diameter slightly larger than the outer diameter of the helical file body 100 so that the circular plate 210 is pushed into the helical file body 100 .

The coupling cylindrical portion 220 may have an outer diameter corresponding to the inner diameter of the helical pile main body 100, and the lower end of the coupling cylindrical portion 220 may be integrally joined to the upper surface of the circular plate 210 by welding.

The coupling cylinder 220 has an outer diameter corresponding to the inner diameter of the helical file main body 100 and is inserted into the lower end of the helical file main body 100 and is inserted into the coupling bolt 241 and the coupling nut 242 And is fixedly coupled to the lower end of the helical file body 100.

Bolt through holes 243 and 244 through which the coupling bolt 241 is inserted are formed in the lower end of the helical file main body 100 and the coupling cylindrical portion 220 so that the coupling cylindrical portion 220 is inserted into the helical file main body 100. [ The coupling bolt 241 is passed through the bolt through holes 243 and 244 while being inserted into the lower end of the coupling bolt 241 and the head coupling nut 242 is fastened to the projecting end portion of the coupling bolt 241 .

The plurality of perforated blades 230 are formed in a right triangle shape so that two orthogonal sides of the perforated blade 230 form an upper side and a vertical side respectively and a hypotenuse is disposed to face the outer periphery of the helical file HP, And the upper side is joined to the lower surface of the circular plate 210 by welding.

The pair of helixes 300 include a cutting plate body 310 having a circular arc surface smaller than a half circle and having an arc surface larger than a quarter circle and installed horizontally, A cutting edge 320 formed to be curved and a cut soil gathers 330 formed upwardly curved at a trailing edge of the cutting plate complement 310.

The helix main body 310 has a lead angle of "0" and is joined at a right angle to the helical filing body 100, so that when the helical filing body 100 is vertically erected, And is configured to be horizontal.

The cutting edge 320 may be formed as a flat plate inclined downward at a predetermined angle from the leading edge of the helix main body 310. However, in order to improve cutting efficiency and structural strength, the cutting edge 320 may be curved in a curved shape .

In addition, the cutting edge 320 may be formed with a sharp cutting edge 321 at its tip to improve cutting efficiency.

The cut soil gathers 330 may be formed as a flat plate inclined upwards at a predetermined angle from the trailing edge of the helix body 310. However, in order to improve the soil gathers efficiency and structural strength, It is preferable to form it into a shape.

The cutting edge 320 and the cutting soil gathers 330 may be integrally formed with the leading edge and the trailing edge of the helix body 310 or may be integrally joined together by welding.

A plurality of cutting guide teeth 340 having an outer diameter equal to the outer diameter of the helix main body 310 are protruded from the bottom edge of the helix body 310.

It is preferable that the protrusion height of the cutting guide blade 340 is lower than the protrusion height of the cutting blade 320 so that the lower end of the cutting guide blade 340 is positioned higher than the lower end of the cutting blade 320.

The plurality of cutting guide blades 340 may be integrally joined to the bottom edge of the helix body 310 by welding.

The thickness t of the cutting guide blade 340 may be T / 2? T? T, where T is the thickness of the helix body 310.

The cutting guide blade 340 cuts the soil layer cut while cutting the cutting edge 320 into a cylindrical shape to guide the center of the helical cutter HP to be always vertical, Two helical bodies 310 are provided at intervals of 180 degrees. However, two helical bodies 310 are provided at two helical bodies 310, and four helical bodies 310 are installed at intervals of 90 degrees as a whole. It is possible.

A plurality of cutting gravel-piece-like guide teeth 350 are formed on the top surface of the helix body 310 so as to protrude from the helix body 310 and have an outer diameter equal to the outer diameter of the helix body 310.

The plurality of cutting gravel-slurry-guiding blades 350 may be lower than the projecting height of the gravel-slurry cutting blades 330 so that the lower end of the slurry-gravel-guiding blade 350 is positioned lower than the top of the slurry- .

The cut soil gravel guide nail 350 can be integrally joined to the top edge of the helix body 310 by welding.

The cut soil gravel blade edge 350 is cut in a cylindrical shape before the cut soil gathers 330 so as to be stacked on the cutting blade main body 310 so that the center of the helical cutter HP is always vertical One helical body 310 is provided for each of the pair of helical bodies 310 and two helical bodies 310 are arranged at an interval of 180 degrees as a whole. Two of each can be installed, and four can be installed at an interval of 90 degrees as a whole.

5, the shaft file SP used together with the big helical file HP according to the present embodiment includes a shaft file body 400 having the same diameter as the helical file body 100, And a coupling head 410 coupled to an upper end of the shaft file main body 400 to connect a hydraulic rotary device mounted on a boom of a backhoe or another shaft file SP.

A connection pin hole 401 corresponding to a connection pin hole 111 formed in the connection head 110 coupled to the upper end of the helical file main body 100 is formed at the lower end of the shaft file main body 400, (410) is formed with a connection pin hole (411) for connecting a hydraulic rotary device or another shaft file (SP).

The operation of the big helical file according to the present embodiment will be described below.

The connecting head 110 connected to the upper end of the helical file main body 100 is connected to the hydraulic rotating device (not shown) by the connecting pin 120 to adjust the boom of the backhoe, So that the perforation head 230 of the perforation head 200 coupled to the lower end of the perforation head 200 contacts the ground.

The entire helical file HP made up of the connecting head 110, the helical file body 100, the perforated head 200 and the helix 300 is moved .

As the big helical file HP rotates, the perforation blade 230 of the perforation head 200 first punctures the ground.

At this time, the plurality of perforated blades 230 are arranged at regular angular intervals, and are formed in a right triangular shape so that two orthogonal sides make up the upper side and the vertical side respectively, and the hypotenuse faces the outer direction of the big helical file HP And the upper side is joined to the lower surface of the circular plate 210 by welding, so that the lower end of the perforation blade 230 and the hypotenuse puncture the ground, It is possible to maintain straightness, and it is possible to drill rocks as well as soft grounds and rigid grounds.

When the cutting edge 321 of the cutting edge 320 of the helix 300 contacts the ground as the ground penetration by the perforated edge 230 progresses, cutting with the cutting edge 321 is performed.

Since the helix 300 is vertically connected to the helical file body 100, when the helical file body 100 connected to the hydraulic rotating device is vertically held, the helix 300 is rotated Since the helical body 310 is formed of an arc-shaped plate having a lead angle of "0 ", the earth pressure generated in the cutting process does not act as a buckling load on the helical file body 100, The file HP can be accurately and vertically penetrated to the ground.

In addition, 100% of the torque is transmitted without loss to the helix body 310 through the helical file body 100 from the hydraulic rotating device as much as no buckling load is generated, so there is no power loss, and the ground cutting and penetration efficiency And it is possible to cut and penetrate rocks as well as soft grounds and rigid grounds.

In this process, the cut soil germination blade 330 formed upwardly curved at the trailing edge of the helix body 310 pushes up the ground gypsum cut by the cutting edge 320 upward, and the helix body 310 It is possible to minimize the load of the cutting gravel acting on the cutting edge 320, so that the loss of the torque can be further minimized.

The arc-shaped cutting guide blades 340 provided on the lower edge of the helix main body 310 cut the ground tortoise cut by the cutting blade 320 into a cylindrical shape again, The circular arc-shaped cutting soil-ground guide blade 350 cuts the ground soil gypsum cut in the cylindrical shape again, thereby enhancing the straightness of the big helical file HP and allowing the big helical file HP to be vertically penetrated .

The operation of the ground drilling by the perforated head 200 and the operation of the ground by the cutting edge 320 of the helix 300 and the action of the cutting guide guide 340 and the cutting soil guide guide 350 are sequentially performed , The hydraulic rotary device is stopped, the big helical file (HP) is separated from the hydraulic rotary device, and the shaft of the big helical file (HP) Connect the file (SP) and connect the top of the shaft file (SP) to the hydraulic rotary unit.

The connection between the big helical file HP and the shaft file SP is achieved by inserting the lower end of the shaft file SP into the connection head 110 coupled to the upper end of the big helical file HP, Through the bolt through hole 111 of the connecting head 110 and the bolt through hole 401 formed at the lower end of the shaft file body 400 of the shaft file SP and the connecting bolt 121 And the connecting nut 122 is fastened to the protruding end portion of the connecting nut.

The shaft file SP connected to the upper end of the big helical file HP is connected to the connecting head 410 connected to the upper end of the shaft file main body 400 by a connecting pin 120 to a hydraulic rotary device do.

When the hydraulic rotary device is operated in this state, the shaft file SP and the big helical file HP connected thereto are rotated, and the above-described boring and cutting process are performed.

Thereafter, another shaft file SP can be connected to the upper end of the shaft file SP according to the penetration depth, and when the final shaft file SP is connected and the penetration is completed, the grouting step and the head ) The completion of the construction process through the summary step and the dynamic test step.

As described above, the big helical file according to the present embodiment has a helix body with a lead angle of "0 " and a cutting edge formed downwardly curved at the leading edge of the helix body and a cutting edge formed at the trailing edge of the helix body, And a cutting edge guide edge provided on a top edge of the helix main body. Thus, even if the present invention is applied to a large helical file as well as a small helical file, a buckling load is not applied in a construction process Therefore, the torque can be minimized because the buckling load is not generated, so that the construction can be performed even with a small torque.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: Helical file body 200: Perforated head
210: disk 220: engaging cylindrical portion
230: perforated edge 300: helix
310: Helix body 320:
330: cutting soil germination blade 340: cutting guide blade
350: cutting soil guide blade 400: shaft file

Claims (1)

A helical file body (100) comprising a circular pipe; A piercing head 200 coupled to a lower end of the helical file body 100; A pair of helixes 300 that are rotationally symmetrically joined to the outer circumferential surface of the helical file body 100 above the perforation head 200; And,
The piercing head 200 includes a circular plate 210 bonded to a lower end of the helical pile body 100 and a circular plate 210 coupled to the upper surface of the circular plate 210 and inserted into the lower end of the helical pile body 100 And a plurality of perforated blades 230 which are formed in a right triangle and are joined to the lower surface of the circular plate 210 and arranged at equal angular intervals,
The disk 210 is formed of an iron plate having an outer diameter larger than the outer diameter of the helical file body 100. The disk 210 is welded to the lower end of the helical file body 100, Is not pushed into the inside of the helical file body (100)
The coupling cylindrical portion 220 is formed to have an outer diameter corresponding to the inner diameter of the helical pile main body 100 and the lower end thereof is integrally joined to the upper surface of the circular plate 210 by welding,
The coupling cylinder 220 has an outer diameter corresponding to the inner diameter of the helical file main body 100 and is inserted into the lower end of the helical file main body 100 and is fixed by the coupling bolt 241 and the coupling nut 242 Is fixedly coupled to the lower end of the helical file body (100)
The plurality of perforated blades 230 are formed in a right triangle shape so that two orthogonal sides of the perforated blade 230 form an upper side and a vertical side respectively and a hypotenuse is disposed to face the outer periphery of the helical file HP, And the upper side is joined to the lower surface of the circular plate 210 by welding,
The pair of helixes 300 include a cutting plate main body 310 having a circular arc surface smaller than a semicircle and having an arc surface larger than a quarter circle and installed horizontally, A cutting edge 320 on which a sharp cutting line portion 321 is formed and a cutting grit sandblasted edge 330 curved upward on the trailing edge of the cutting plate complement 310,
The helix main body 310 has a lead angle of "0" and is joined at a right angle to the helical filing body 100, so that when the helical filing body 100 is vertically erected, And is configured to be horizontal,
A plurality of cutting guide teeth 340 formed in an arc shape and having an outer diameter equal to the outer diameter of the helix main body 310 are formed on the bottom edge of the helix main body 310. The protruding height of the cutting guide teeth 340 is, The protruding height of the protruding portion is set to be smaller than the protruding height
The helix body 310 has a plurality of cutting gravel-piece-like guide blades 350 formed in an arc shape having an outer diameter equal to the outer diameter of the helix body 310 and protruding to a height lower than the protrusion height of the cutter gravel- Installed,
In order to increase cutting efficiency and structural strength, the cutting edge 320 is curved in a curved shape,
Wherein the cut soil gathers (330) is formed in a curved shape in a curved shape in order to improve the soil gath- ering efficiency and the structural strength.

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