KR102195847B1 - File coupling structure with spiral plate - Google Patents

Abstract

The present invention is an improved invention of patent registration No. 10-0690014, used as a pile, nailing, and ground anchor, and combines the line and trailing piles to engage in an uneven shape, and the rotational force of the trailing pile is well transmitted to the preceding piles. This is achieved by providing a pile coupling structure having a spiral plate into which the pile is inserted into the ground while the rotational compression force is increased.This is achieved by providing a pile coupling structure having a number of spiral plates formed on the outer circumferential surface, in which an inclined projection and an inclined groove are formed continuously and repeatedly at the top. A preceding file formed with a portion and a locking jaw, a locking jaw protruding to the outside on the lower front side of the inclined projection and a bolt hole through the outer surface; A trailing pile in which an inclined protrusion and an inclined groove are continuously repeatedly formed at the top and bottom, and a locking groove is formed on the inner front surface of the inclined groove; A coupler that is welded to the outer surface of the lower uneven portion of the trailing pile, the inner diameter is the same as the outer diameter of the preceding/following pile, the inner surface is inclined and the engaging groove is formed on the upper side, and the bolt hole is passed through the outer surface; By coupling the locking jaws of the preceding pile to the locking grooves of the coupler, and using bolts and nuts in the bolt holes of the preceding pile and coupler, the coupler and the preceding pile are united. Is inserted into.

Description

File coupling structure with spiral plate}

The present invention is an improved invention of the patent registration No. 10-0690014, used as a pile, nailing, and ground anchor, and the line and the trailing file are combined so that they are engaged in an uneven shape, and the rotational force of the trailing file is well transmitted to the preceding file. As the rotational compression force is increased, it is a pile coupling structure having a spiral plate into which the pile is inserted into the ground.

In general, when constructing a building, a foundation plate is constructed to prevent the collapse of the building due to ground breaking, while connecting the foundation pile embedded in the basement and the pillars on the ground. Such a foundation plate is generally formed of reinforced concrete. .

However, even though the foundation plate is formed in this way, if the ground subsidence occurs, the building is tilted to one side and a crack occurs, resulting in a risk of collapse.

In order to prevent such a phenomenon, circular steel pipe piles are rotated into the ground under the foundation plate, and the steel pipe piles easily bend when working on the hard ground, and the durability against lateral forces is weak. In the process, if an excessive vertical force was applied, it could not be overcome and a problem occurred in which it was bent in one direction.

In addition, in the process of driving steel pipe piles into the ground, steel pipes of a certain length are welded up and down or connected using bolts.Because the welding of the upper and lower steel pipe piles is done only at the end, there is a disadvantage that the bonding strength is weak against impact during construction, and the bolt connection is strong. The bolt is cut or bent by the torque.

In particular, the welding of the upper and lower steel pipe piles is performed at the site during work.If the welding is wrong or the bonding strength is weak, the welding surface falls and the ends of the upper and lower steel pipes are separated, so that the piles that are infiltrated with rotation can no longer be constructed.

In addition, in the case of the bolt connection, there is a problem that the bolt is easily cut and bent due to a strong rotational force, so that the pile cannot be penetrated anymore. Therefore, if the pile is not constructed deeply, the structure may settle or unequal settlement due to insufficient support and crack or collapse.

In order to solve this problem, the applicant's pre-registered patent No. 10-0690014 "Steel structure with spiral plate" can be applied as a file.

As shown in the accompanying drawings, the steel material having the spiral plate includes a steel material 10 having a ground inlet 11 formed at the lower end, and a plurality of steel materials formed on the outer circumferential surface of the steel material 10 and having a diameter longer than that of the steel material. It consists of a helical plate 20 and a coupling means 30 for connecting the steel 10 having the helical plate 20 to each other.

My pre-registered patent is that a spiral plate is formed on the outer circumferential surface of a steel material, and the ground and the spiral plate are interlocked, so that the compressive force and tensile force of the structure are transferred to the ground to ensure stability.

In addition, the coupling means 30 for coupling the two steel materials to each other expands one end of the steel material 10a made of a circular tube, as shown in the accompanying drawings Figure 2, and expands the steel material 10b of the other circular tube. It is a structure to fix them by fastening them with bolts 15 and nuts 16 after inserting them.

However, when the two steel materials joined by the coupling means rotate, there is a regret that the rotational compression force cannot be increased because the connection part does not reflect the rotational force well.

Korean Patent Registration No. 10-0690014 "Steel structure with spiral plate"

The present invention was developed to solve the above problems, and its purpose is to use it as a file inserted into the ground, nailing and ground anchor, and by combining the preceding and following files to engage in uneven form, the combination between the files is It is sturdy and at the same time that the rotational force of the trailing pile is well transmitted to the preceding pile, so that the compression force increases, and the pile joint structure is provided with a spiral plate into which the pile is inserted into the ground.

The object of the present invention is achieved by providing a pile coupling structure having a helical plate that allows the rotational force of the trailing pile to be well transmitted to the preceding pile in a combined state in the uneven shape, which is in the preceding pile having a plurality of helical plates formed on the outer circumferential surface. , The inclined protrusion and the inclined groove are formed continuously and repeatedly formed uneven portion and the locking protrusion, the locking protruding to the outside on the lower front of the inclined protrusion, and the preceding pile through which the bolt hole is penetrated; A trailing pile in which an inclined protrusion and an inclined groove are continuously repeatedly formed at the top and bottom, and a locking groove is formed on the inner front surface of the inclined groove; A coupler that is welded to the outer surface of the lower uneven portion of the trailing pile, the inner diameter is the same as the outer diameter of the preceding/following pile, the inner surface is inclined and the engaging groove is formed on the upper side, and the bolt hole is passed through the outer surface; And coupling the locking jaws of the preceding pile to the locking groove of the coupler, and using bolts and nuts in the bolt holes of the preceding pile and the coupler so that the coupler and the preceding pile become one body.

The pile coupling structure having a spiral plate according to the present invention is used as a pile, nailing, and ground anchor inserted into the ground. Since the preceding pile and the following pile are interlocked in an uneven shape, the rotational force of the following pile is well transmitted to the preceding pile. It has the effect of increasing the rotational compression force.

In addition, since the coupler and the preceding pile are fixed with bolts and nuts, there is an effect of stably rotating by blocking the preceding pile from being separated from the coupler.

1 is a front view showing the configuration of the person's pre-registered patent
Fig. 2 is a cross-sectional view showing a means of combining a pre-registered patent
3 is a perspective view showing the overall configuration of the present invention
4 to 5 are perspective views showing another configuration of the present invention
6 to 15 are cross-sectional views and perspective views showing another configuration of the present invention
16 is a view showing a state of use of the present invention

Hereinafter, specific details for a preferred implementation of the present invention will be described in detail with reference to FIG. 3 in the accompanying drawings.

The present invention is to provide a pile coupling structure having a spiral plate used as a pile inserted into the ground while the rotational force of the trailing pile is well transmitted to the preceding pile.

The pile coupling structure 200 having such a helical plate is made of a preceding pile 210 having an uneven portion and a trailing pile 220 provided with a coupler 230, and combines the uneven portions so as to engage with each other to become one body.

The preceding pile 210 is a metal circular tube, and it is easy to insert into the ground by forming a pointed ground insertion hole 11 at the bottom, and a spiral plate with a diameter larger than that of the preceding pile 210 on the outer circumferential surface at regular intervals A number of (20) are provided.

A concave portion 211 and a convex portion 212 are formed at the upper end of the preceding pile 210 so as to be continuously repeated.

The trailing pile 220 is a metal circular tube, and the concave portion 221 and the convex portion 222 are continuously repeated at the top and bottom to form upper and lower uneven portions 223 and 223', and the lower uneven portion A coupler 230 is installed on the outer surface of (223').

The coupler 230 is a circular tube, and the inner diameter is the same as the outer diameter diameter of the preceding pile 210 and the trailing pile 220.

The coupler 230 is fixed by welding 235 after fastening to the outer surface of the lower uneven portion 223'.

Then, the concave-convex portion 213 of the preceding pile 210 is coupled to the concave-convex portion 223' of the trailing pile 220 located inside the coupler 230.

At this time, the convex portion 212 of the uneven portion 213 is inserted into the concave portion 221 of the lower uneven portion 223', and the uneven portion 213 is in the convex portion 222 of the lower uneven portion 223' The concave portion 211 is inserted and the gears are coupled to each other in a meshing manner to form a solid coupling.

Since the outer surface of the preceding pile 210 is in close contact with the inner surface of the coupler 230 and the uneven parts 213 and 223' are engaged with each other, the rotational force of the trailing pile 220 is well applied to the preceding pile 210. As it is transmitted, the following file 220 and the preceding file 210 are rotated in the same direction.

In addition, as shown in the drawing attached to the upper end of the preceding pile 210, as shown in Fig. 4, the inclined protrusion 215 and the inclined groove 217 are formed to be continuously repeated to form an uneven portion 213, and the inclined protrusion 215 To form a locking projection 216 protruding to the outside on the lower front side of the.

At the top and bottom of the trailing pile 220, an inclined protrusion 225 and an inclined groove 226 are formed to form an uneven portion 229 continuously repeated, and a locking groove 227 on the inner front surface of the inclined groove 226 To form.

Then, a coupler 230 having an inner diameter equal to the outer diameter of the preceding pile 210 and the trailing pile 220 is welded 235 to the outer surface of the uneven portion 229 of the trailing pile 220 to be fixed.

Then, as shown in FIG. 5, the uneven portion 213 of the preceding pile 210 is coupled to the uneven portion 229 of the trailing pile 220 located inside the coupler 230 as shown in FIG. 5.

At this time, the inclined protrusion 215 of the uneven portion 213 is inserted and coupled to the inclined groove 226 of the uneven portion 229, and the locking jaw 216 is fastened to the locking groove 227, and the uneven portion 229 The inclined protrusion 225 of the inclined groove 217 of the uneven portion 213 is inserted and coupled to form a gear meshing with each other to achieve a solid coupling.

As a result, the rotational force of the trailing pile 220 is well transmitted to the preceding pile 210, so that the trailing pile 220 and the preceding pile 210 rotate in the same echo.

Since the pile of the preceding pile 210 and the trailing pile 220 is directly inserted into the ground without the need for a drilling operation, construction processes such as drilling work, grouting, and grout curing are reduced, so that the construction time and construction cost can be reduced.

In addition, the rotational force of the trailing file 220 is well transmitted to the preceding file 210 to become a compression force, so that the file can be easily inserted.

Another embodiment of the present invention will be described with reference to FIGS. 6 and 7 in the accompanying drawings.

A bolt hole 231 is formed to penetrate through the outer surface of the coupler 230 welded 235 to the lower uneven portion 223' of the trailing pile 220, and a bolt hole on the upper side of the preceding pile 210 to correspond thereto (215) is formed to penetrate.

After firmly coupling the concave-convex portion 213 of the preceding pile 210 to the concave-convex portion 223' of the trailing pile 220 located inside the coupler 230, bolt holes 231, 215 The bolt 350 is inserted into and fixed by fastening the nut 340.

The above-described coupling structure is used when a large tensile force acts on the preceding pile 210, and prevents the preceding pile 210 from being separated from the following pile 220, and a safe rotational force is ensured.

Another embodiment of the present invention will be described with reference to FIGS. 8 and 9 in the accompanying drawings.

The inner surface of the coupler 230 is inclined at a certain angle to form a locking groove 235 on the upper inner circumferential surface, and a locking projection 218 protruding outward on the upper outer circumferential surface of the preceding pile 210 is formed.

The preceding pile 210 is inserted into the inclined interior of the coupler 230 and is pushed and coupled until the locking projection 218 is inserted into the locking groove 235. At this time, since the inner surface of the coupler 230 is formed to be inclined, fastening of the preceding pile 210 is facilitated.

Further, another embodiment of the present invention will be described with reference to FIGS. 10 and 11 in the accompanying drawings.

Among the uneven portions 213 of the preceding pile 210, locking projections 217 protruding outwardly are formed on both upper ends of the convex portions 212, and the concave portions 221 of the uneven portions 223 of the trailing pile 220 ) To form a locking groove 227 at the top.

When the convex portion 212 of the preceding pile 210 is inserted into the concave portion 221 of the following pile 220, the locking jaw 217 is inserted into the locking groove 227 and fixed.

Since the concave portion 221 is formed to be inclined, it is easy to insert the convex portion 212.

In another embodiment of the present invention, the inner coupler 260 is installed to protrude to the outside on the inner circumferential surface of the lower uneven portion 223 ′ of the trailing pile 220 as shown in FIGS. 12 and 13.

The inner coupler 260 is a circular tube, and is fixed to the inner circumferential surface of the uneven portion 213 of the preceding pile 210 through welding 235.

When the uneven portion 213 of the preceding pile 210 is coupled to the lower uneven portion 223 of the following pile 220, the internal coupler 260 is inserted into the interior of the preceding pile 210 and is connected to each other.

That is, since the uneven parts 213 and 223' are engaged and coupled with each other, the internal coupler 260 supports the preceding pile 210 and the trailing pile 220, so that a strong and safe coupling is achieved.

In addition, another embodiment of the present invention, as shown in the accompanying drawings 14 and 15

An internal coupler 260 is installed on the inner circumferential surface of the uneven portion 213 of the preceding pile 210, and a coupler 230 is installed on the outer peripheral surface of the rear uneven portion 223' of the trailing pile 220.

When the concave-convex portion 213 of the preceding file 210 is coupled to the concave-convex portion 223 of the trailing file 220, the internal coupler 260 is inserted into the preceding file 210 and at the same time, the trailing file 220 ) Is in close contact with the inner surface of the coupler 230 and is double-coupled.

In the present invention as described above, the uneven portion 213 of the preceding file 210 provided with the spiral plate 20 is closely inserted into the coupler 230 of the trailing file 220 as shown in FIG. A file having a length desired by the user may be formed by being coupled to the lower uneven portion 223 ′ of the file 220 and connecting the other trailing file 220 in an uneven shape.

Then, when the trailing pile 220 is installed on the drilling machine and rotated, the preceding pile 210 and the trailing pile 220 are engaged with each other in an uneven shape and rotate while being supported by the coupler 230.

At this time, while the rotational force of the trailing pile 220 is well transmitted to the preceding pile 210, the leading and trailing piles 210 and 220 rotate stably with each other and at the same time, the compression force is increased and inserted into the ground.

As described above, an exemplary embodiment of the present invention has been described, but the present invention is not limited thereto and may be changed within the scope described in the claims.

210: lead file 211,221: recess
212,222: convex portion 213: uneven portion
220: trailing file 223: upper irregularities
223'; bottom uneven portion 230: coupler
231: bolt hole 235: welding
240: nut 250: bolt
260: internal coupler

Claims (5)

delete In the preceding pile in which a number of spiral plates are formed on the outer circumferential surface,
A preceding pile in which an inclined protrusion and an inclined groove are formed in an uneven portion and a locking jaw in which the inclined protrusion and the inclined groove are continuously repeated, and a locking jaw protruding outward on the lower front side of the inclined protrusion and a bolt hole through the outer surface thereof;
A trailing pile in which an inclined protrusion and an inclined groove are continuously repeatedly formed at the top and bottom, and a locking groove is formed on the inner front surface of the inclined groove;
A coupler that is welded to the outer surface of the lower uneven portion of the trailing pile, the inner diameter is the same as the outer diameter of the preceding/following pile, the inner surface is inclined and the engaging groove is formed on the upper side, and the bolt hole is passed through the outer surface;
A pile coupling structure having a helical plate comprising coupling the hooking jaws of the preceding pile to the hooking groove of the coupler, and using bolts and nuts in the bolt holes of the preceding pile and the coupler so that the coupler and the preceding pile become one body. delete delete delete

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