KR20230126337A - Underground Fixed Piles - Google Patents

Abstract

The present invention relates to a pile for fixing a structure in the ground, and more particularly, to a main body inserted into the ground; a rotating body inserted into the main body and formed so that the upper screw and the lower screw are wound in opposite directions; and upper and lower fixtures in which the upper and lower springs are extended to the outside of the main body while moving up and down along the rotating body, and the upper and lower springs can be extended with little force and are deployed in a large area in the ground. It relates to an underground anchoring pile with enhanced anchoring force.

Description

Underground Fixed Piles {Underground Fixed Piles }

The present invention relates to a pile for fixing a structure in the ground, and more particularly, to a main body inserted into the ground; a rotating body inserted into the main body and formed so that the upper screw and the lower screw are wound in opposite directions; and upper and lower fixtures in which the upper and lower springs are extended to the outside of the main body while moving up and down along the rotating body, and the upper and lower springs can be extended with little force and are deployed in a large area in the ground. It relates to an underground anchoring pile with enhanced anchoring force.

In general, since the soil is exposed to the outside of the bare land soft ground existing in mountains, roads, rivers, parks, or residential areas, soil erosion is accelerated due to the outflow of soil due to the influence of rain or customs. Due to this erosion, landslides and floods frequently occur during rainy weather, causing many casualties.

Before constructing a structure on soft ground, the ground must be reinforced according to the size and use of the structure.

In addition, in order to construct various structures, it is essential to reinforce the soft ground on which the structure is built to prevent differential settlement while stably supporting the surface load of the structure. Accordingly, the scale of the structure , various types of reinforcement methods are disclosed according to the purpose of use and the structure of the soil layer of the soft ground.

These soft ground countermeasure methods can be largely classified into the improvement method and the support pile method. For example, the improved method includes a sand drain method, a vertical drain method, a paper drain method, a pack drain method, a sand compaction pile method, a dynamic compaction method, and a compacted soil method.

However, in this soft ground improvement method, if the improvement depth is too deep or the improvement range is wide, it takes a lot of time and cost due to concrete curing. There are more and more examples of using it as a construction method for supporting the embankment body.

The support pile construction method is a method of constructing a soil embankment and an upper structure by using steel pipe piles to support piles on the solid ground below the soft ground and laying geotextiles on the top of the piles.

These conventional pile construction methods are usefully used in urban construction sites, and in-situ construction sites have mainly adopted on-site pile construction with relatively low vibration and noise.

The foundation pile constructed in this way has the advantage of efficiently handling the load of the ground structure by maintaining an appropriate frictional force with the surrounding ground.

However, since the soft ground is saturated with a large amount of moisture in the cohesive soil forming the soft ground, the bearing capacity and strength of the ground due to external pressure are weak. In addition, if the ground surface subsides to some extent, even if it is possible to install a structure, due to the nature of soft ground, a large amount of consolidation settlement continues over a long period of time, so the damage to the structure installed on the soft ground is great over time. Since it has been lost, it is difficult for the foundation piles constructed as field strikes to maintain proper frictional force with the surrounding ground in loose or soft ground layers such as general soil.

The soft ground support reinforcement structure disclosed in Korean Patent Registration No. 10-2066505 for improving these disadvantages is inserted and installed in the ground in the longitudinal direction formed by the main support and auxiliary support, and the side plate provided on the rotating plate As it unfolds, it can increase the contact area with the ground and stably bind it to the ground.

However, in order for the side plate to unfold in the ground, the side plate must push out the soil, sand, etc. Formed as a space, it is not enough to reinforce the bearing capacity.

In addition, as the side plate expands to contact the ground in a large area, the ground must be pushed more and the force applied to the pile from the ground increases, so the difficulty of the work increases and a lot of power is consumed, resulting in economic loss. do.

Therefore, in piles installed to reinforce soft ground, the development of piles that are easy to install and can be stably fixed by extending to a large area with little power is emerging.

KR 10-2066505 (B1) 2020.01.09. KR 10-2060103 (B1) 2019.12.20.

In order to solve the above problems, an object of the present invention is to insert and install the main body in the ground, insert a rotating body having an upper screw and a lower screw inside the main body, and the upper and lower springs are main according to the rotation of the rotating body. Since it is deployed outside the body and expands the contact area with the ground, it is to provide a ground fixing pile that can be stably and firmly fixed in the ground.

Another object of the present invention is that when the upper and lower springs wound along the outer periphery of the rotating body are deployed to the outside of the main body through the outlet, they are rotated in a spiral and deployed through the ground so that they can be easily expanded with little force. It does not hinder the density of the ground, and since the outer surfaces of the upper and lower springs are supported by the ground, it provides a ground-fixed pile with enhanced fixing power.

Another object of the present invention is that the upper and lower screws of the rotating body are wound in opposite directions to each other, and the upper and lower fixing bodies are raised and lowered along the upper and lower screws, respectively, so that the upper and lower fixing bodies are rotated in the forward direction of the rotating body. It is to provide an underground fixed pile that does not sink in the ground by supporting the force acting vertically as it rises in a direction away from each other and the upper and lower springs gradually increase in diameter and expand and expand to the outside of the main body.

Another object of the present invention is to rotate the rotating body in reverse so that the upper and lower springs deployed in the ground can be stored inside the main body through the outlet to recover the upper and lower springs, so that the stakes fixed in the ground can be easily removed. It is to provide underground fixing piles.

In the present invention for achieving the above object, in a pile that is inserted into the ground and fixed, a pointed tip 110 is formed at the bottom, the inside is formed hollow, and the top is open to communicate with the inside, The main body 100 in which the outlet 140 penetrating the inside and outside is formed; It is inserted into the inside of the main body 100, a lower screw 230 wound in a certain direction is formed at the bottom, and an upper screw 220 wound in a direction opposite to the direction of the lower screw 230 is the lower screw ( 230) the rotating body 200 formed on the top; An upper bolt 310 that moves up and down along the upper screw 220 is provided, and an upper plate 320 formed with a smaller diameter than the size of the upper bolt 310 is rotatably coupled to the upper bolt 310. And, one end is coupled to the top plate 320 and the upper fixture 300 is provided with an upper spring 330 surrounding the outer periphery of the rotating body 200; And a lower bolt 410 that moves up and down along the lower screw 230 is provided, and a lower plate 420 formed with a smaller diameter than the size of the lower bolt 410 is rotatably coupled to the lower bolt 410. and a lower fixture 400 having one end coupled to the lower plate 420 and having a lower spring 430 surrounding the outer periphery of the rotating body 200.

In addition, the upper spring 330 and the lower spring 430 of the present invention are drawn out of the main body 100 through the outlet 140 and are expanded to gradually increase in diameter by elastic force.

In addition, the upper bolt 310 and the lower bolt 410 of the present invention are in contact with the inner circumferential surface 130 of the main body 100, and are lifted without rotation along the longitudinal direction of the rotating body 200.

In addition, when the rotating body 200 of the present invention rotates forward, the upper and lower fixtures 300 and 400 are lifted apart from each other, and the upper spring 330 and the lower spring 430 are connected to the outlet. It is drawn out of the main body 100 through 140.

In addition, during the reverse rotation of the rotating body 200 of the present invention, the upper stator 300 and the lower stator 400 are raised and lowered so as to approach each other, and the upper spring 330 and the lower spring 430 are It is accommodated inside the main body 100.

In the underground fixing pile according to the present invention, the main body is inserted and installed in the ground, a rotating body having an upper screw and a lower screw is inserted into the main body, and the upper and lower springs are moved outside the main body according to the rotation of the rotating body. It is deployed and expands the contact area with the ground, so it has the advantage of being stably and firmly fixed in the ground.

In addition, in the present invention, when the upper and lower springs wound along the entire outer periphery are deployed to the outside of the main body through the outlet, they are rotated in a spiral and deployed through the ground, so that they can be easily expanded with little force and It does not hinder the density and has the advantage of strengthening the fixing force because the outer surfaces of the upper and lower springs are supported by the ground.

In addition, the present invention is formed by winding the upper and lower screws of the rotating body in opposite directions, and the upper and lower fixing bodies are raised and lowered along the upper and lower screws, respectively, so that the upper and lower fixing bodies mutually interact with each other during forward rotation of the rotating body. As it rises and falls in the direction away from it, and the diameter of the upper and lower springs gradually increases, it expands and expands to the outside of the main body, so it supports the force acting vertically and does not sink from the ground.

In addition, the present invention has the advantage of being able to easily remove the piles fixed in the ground because the upper and lower springs deployed in the ground are stored in the main body through the outlet by rotating the rotating body in reverse, and the upper and lower springs can be recovered. there is.

1 is an exploded perspective view of the underground fixed pile of the present invention.
Figure 2 is a cross-sectional view of the state before the upper and lower springs according to the underground fixed pile of the present invention are deployed to the outside of the main body.
Figure 3 is a cross-sectional view of a state in which the upper and lower springs according to the underground fixed pile of the present invention are deployed to the outside of the main body.
In addition, 4 shows a state in which the ground fixing pile of the present invention is fixed to the ground, (a) is a cross-sectional view of a state in which the rotating body is rotated using a manual rotating device, (b) is a rotating device that is rotated by the power of heavy equipment A cross-sectional view of a state in which a rotating body is rotated using

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention will be described so that those skilled in the art can easily implement it.

In the present invention, when described as upper and lower parts, it means that the upper and lower components are collectively referred to. For example, the upper and lower fixtures 300 and 400 refer to both the upper fixture 300 and the lower fixture 400 . In addition, in the present invention, the forward rotation direction of the rotating body 200 means the direction in which the upper and lower springs 330 and 430 extend to the outside of the main body 100, and the reverse rotation direction of the rotating body 200 refers to the upward, This means the direction in which the lower springs 330 and 430 are received into the main body 100 .

As shown in FIGS. 1 to 4, the ground-fixed pile according to the present invention is a pile inserted and fixed into the ground to firmly install the structure on bare land,

A main body 100 having a pointed tip 110 formed at the lower end, a hollow interior, an upper end open to communicate with the inside, and an outlet 140 penetrating the inside and outside;

It is inserted into the inside of the main body 100, a lower screw 230 wound in a certain direction is formed at the bottom, and an upper screw 220 wound in a direction opposite to the direction of the lower screw 230 is the lower screw ( 230) the rotating body 200 formed on the top;

An upper bolt 310 that moves up and down along the upper screw 220 is provided, and an upper plate 320 formed with a smaller diameter than the size of the upper bolt 310 is rotatably coupled to the upper bolt 310. And, one end is coupled to the top plate 320 and the upper fixture 300 is provided with an upper spring 330 surrounding the outer periphery of the rotating body 200; and

A lower bolt 410 that moves up and down along the lower screw 230 is provided, and a lower plate 420 formed with a smaller diameter than the size of the lower bolt 410 is rotatably coupled to the lower bolt 410, , a lower fixture 400 having one end coupled to the lower plate 420 and having a lower spring 430 surrounding the outer periphery of the rotating body 200.

The underground anchoring pile according to the present invention is a pile that reinforces the ground to construct a structure such as a building on bare land, and is deeply embedded in the ground to transmit and support the load of the structure to the ground.

Even when the ground to which the structure is to be fixed is soft ground, it helps the structure to be constructed by reinforcing and reinforcing the ground through the ground fixing pile of the present invention.

As shown in FIGS. 1 and 2, the ground fixing pile according to the present invention is inserted deep into the ground, the main body 100 whose outer surface is in contact with the ground, the main body 100 Rotating body inserted into the main body 100 (200), upper and lower fixing bodies (300, 400) are provided that are moved up and down by forward and reverse rotation of the rotating body (200).

When the main body 100 is deeply driven into the ground to fix the structure and installed in the ground, and the rotating body 200 disposed inside the main body 100 is rotated forward, the phase formed on the rotating body 200, The upper and lower fixing bodies 300 and 400 are moved up and down by the lower screws 220 and 230.

3, the upper fixture 300 expands the upper spring 330 to the outside of the main body 100 while rising to support the ground, and the lower fixture 400 lowers the lower spring 430 to the main body. It is deployed outside the body 100 to support the ground. That is, the upper and lower springs 330 and 430 are deployed outside the main body 100 to expand the contact area with the ground, so that the ground-fixed pile of the present invention is stably and firmly supported.

When the rotating body 200 is rotated in reverse, as shown in FIG. 3 and changed from FIG. While being received inside the main body 100, the support state with the ground is released. Therefore, the underground anchoring pile of the present invention can be easily pulled out by reversely rotating the rotating body 200 to remove the underground anchoring pile of the present invention from the ground.

As shown in FIGS. 1 to 3, the main body 100 according to the present invention is a configuration that is inserted and installed deeply in a vertical direction or inclined in the ground, and may be formed of a concrete material having high compressive strength. However, the application of the material may be variously employed according to the needs of a person skilled in the art.

The main body 100 is formed long in the vertical direction, and a sharp tip 110 is formed at the end of the lower end. The tip 110 is configured to allow the main body 100 to be smoothly inserted into the ground. As the main body 100 is inserted into the ground, it can be conveniently inserted without great resistance.

The inside of the main body 100 is formed hollow. The inner circumferential surface 130 of the main body 100 may be formed in a polygonal shape, and may be contacted with or engaged with upper and lower bolts 310 and 410 to be described later. The upper and lower bolts 310 and 410 do not rotate in contact with the inner circumferential surface 130 of the main body 100 while moving up and down along the longitudinal direction of the rotating body 200 to be described later.

The inner circumferential surface 130 is formed in a polygonal shape in order to lift and lower the upper and lower bolts 310 and 410 without rotation. However, it is not limited to this, and a long groove (not shown) is formed on the inner circumferential surface 130 in the vertical direction of the main body 100, and a protrusion (not shown) inserted into the long groove is formed on the upper and lower bolts 310 and 410. By doing so, the protrusion is caught in the janghom, so that rotation is limited and it can be configured to be limited only to movement in the vertical direction. According to one embodiment of the present invention, it is shown in a hexagonal shape in the drawings.

The inner diameter of the inner circumferential surface 130 may be the same as or slightly larger than the outer diameter of the upper and lower bolts 310 and 410 . As the rotating body 200 rotates, when the upper and lower bolts 310 and 410 coupled to the rotating body 200 try to rotate, the inner diameter of the inner circumferential surface 130 is sufficient to come into contact with the inner circumferential surface 130 to limit rotation. do.

The body head portion 120 formed at the upper end of the main body 100 is open, and the rotating body 200 can be inserted therein. The opened body head part 120 communicates with the hollow inside of the main body 100 . The rotating body 200 is drawn into the inside of the main body 100 through the open top and is disposed.

The body head portion 120 is configured to support a load by contacting a structure to be constructed. The body head portion 120 may be formed larger than the diameter of the main body 100, and when the main body 100 is inserted into the ground, the body head portion 120 is not inserted into the ground and It can be located at the same height as

The load can be transmitted to the main body 100 by bringing the lower surface of the structure to be constructed into contact with the body head 120, and since the main body 100 is fixed to the ground, the load is distributed to the ground.

The main body 100 is formed with an outlet 140 through which the upper and lower springs 330 and 430 to be described later are drawn out. The outlet 140 is bored through the inside and outside of the main body 100 .

One or more outlets 140 may be formed at an upper part and at least one at a lower part based on an upper and lower boundary line 240 to be described later. The outlet 140 is a hole through which the upper and lower springs 330 and 430 are withdrawn. The number of upper springs 330 provided in the upper fixture 300 and the lower spring 430 provided in the lower fixture 400 The number of outlets 140 is provided according to the number of.

That is, when the upper fixture 300 is provided with two upper springs 330, two outlets 140 are formed on the upper part based on the upper and lower boundary lines 240, and the lower spring 430 is attached to the lower fixture 400. ) When two are provided, two outlets 140 are formed at the bottom based on the upper and lower boundary lines 240, so that a total of four are formed.

In the drawing according to an embodiment of the present invention, the upper and lower springs 330 and 430 are provided in the upper and lower fixtures 300 and 400, respectively, so that the outlet 140 is formed in two, but is not limited thereto, and various can transform

When a plurality of upper and lower springs 330 and 430 are provided in the upper and lower fixtures 300 and 400, respectively, the outlet 140 formed at the upper part based on the upper and lower boundary lines 240 has the same height, They may be spaced at equal intervals in the circumferential direction, and the outlets 140 formed at the lower portion based on the upper and lower boundary lines 240 may also be formed at the same height but spaced apart from each other at equal intervals.

When the rotating body 200 rotates forward, the upper and lower springs 330 and 430 disposed inside the main body 100 come out through the outlet 140 and extend to the outside of the main body 100, expand

During reverse rotation of the rotating body 200, the upper and lower springs 330 and 430 extended to the outside of the main body 100 can be stored while being returned to the inside of the main body 100 through the outlet 140. .

The outlet 140 is provided singly or in plurality at the upper and lower sides of the upper and lower boundary lines 240, respectively. It is formed at a higher or the same position, and the outlet 140 located below the upper and lower boundary lines 240 is formed at a position lower than or the same as the lower end of the lower screw 230 to be described later.

The withdrawal port 140 is configured to withdraw the upper and lower springs 330 and 430 , and the upper and lower springs 330 and 430 are drawn out or collected according to the elevation of the upper and lower bolts 310 and 410 . If the upper and lower bolts 310 and 410 are raised and lowered higher than the height of the corresponding outlet 140, a large load is applied to the upper and lower springs 330 and 430, resulting in damage. Therefore, in order to eliminate this risk, the height of the outlet 140 is limited according to the height of the upper and lower screws 220 and 230, as described above.

The outlet 140 is formed obliquely along the inclination of the upper and lower springs 330 and 430 . Therefore, while the upper and lower springs 330 and 430 slide due to the inclination of the outlet 140, the main body 100 can be drawn out or returned to the inside.

As shown in FIGS. 1 to 3 , the rotating body 200 inserted into the main body 100 is configured to elevate the upper and lower fixing bodies 300 and 400 to be described later. The upper and lower springs 330 and 430 may be extended to the outside of the main body 100 or retrieved to the inside while the upper and lower fixtures 300 and 400 are moved up and down.

The rotating body 200 is formed in a cylinder, and a screw is formed on the outer periphery.

The screw formed on the outer periphery of the rotating body 200 is doubled according to the height. A lower screw 230 is formed from the lower end of the rotating body 200 to a certain height, and an upper screw 220 is formed from the upper end of the lower screw 230. The lower screw 230 and the upper screw 220 are wound in opposite directions. An upper and lower boundary line 240 is formed between the upper screw 220 and the lower screw 230 .

That is, the lower screw 230 is formed at the lower part based on the upper and lower boundary line 240, and the upper screw 220 wound opposite to the lower screw 230 is formed at the upper part of the upper and lower boundary line 240.

Upper and lower bolts 310 and 410, which will be described later, are coupled to the upper and lower screws 220 and 230. The upper and lower screws 220 and 230 are threaded in opposite directions, and the threads formed on the inner surfaces of the upper and lower bolts 310 and 410 are identically formed.

Accordingly, when the rotating body 200 rotates, the upper and lower bolts 310 and 410 move up and down in opposite directions. When the rotating body 200 rotates forward, the upper bolt 310 rises and the lower bolt 410 descends. When the rotating body 200 rotates reversely, the upper bolt 310 descends and the lower bolt 410 rises.

The lower end of the lower screw 230 is formed to a height equal to or slightly higher than the height of the outlet 140 located below the upper and lower boundary line 240, and the upper end of the upper screw 220 is formed to the upper and lower boundary line 240. ) It is preferably formed to a height equal to or slightly lower than the height of the outlet 140 located at the top of the.

The lower screw 230 may be formed from the upper and lower boundary line 240 to the lower end, but the upper screw 220 is not formed from the upper and lower boundary line 240 to the upper end, but only to a certain height. No thread is formed from the upper end of the upper screw 220 to the upper end of the rotating body 200 . When the rotating body 200 rotates forward, the upper bolt 310 rises along the upper screw 220, and the upper end of the upper screw 220 is prevented from rising above the height of the outlet 140. is formed lower than the height of the outlet 140 above the upper and lower boundary lines 240.

In addition, to prevent the lower bolt 410 from descending further than the outlet 140 located below the upper and lower boundary line 240, the lower end of the lower screw 230 is the outlet located below the upper and lower boundary line 240. It is formed higher than the height of (140).

A rotation groove 210 is formed at an upper end of the rotation body 200 . The rotating groove 210 is a groove into which the rotating device 500 for rotating the rotating body 200 is inserted.

As shown in FIG. 4 , the rotating device 500 may be a handle that is turned by hand by an operator, or may be a device that is rotated by the power of heavy equipment to rotate with a stronger force.

The rotation device 500 is inserted into the rotation groove 210 to rotate the rotation body 200 . When the rotation device 500 is inserted into the rotation groove 210 and torque is applied, the rotation body 200 rotates forward or backward.

When the rotating body 200 rotates forward, the upper and lower fixing bodies 300 and 400 move up and down so that the upper and lower springs 330 and 430 are deployed and expanded outside the main body 100, and the rotating body 200 ) is rotated in reverse, the upper and lower fixtures 300 and 400 come closer to each other, and the upper and lower springs 330 and 430 are returned to the inside of the main body 100.

As shown in FIGS. 1 to 3, the upper and lower fixtures 300 and 400 disposed on the outer periphery of the rotating body 200 move up and down along the longitudinal direction of the rotating body 200, thereby maintaining contact with the ground. It is a configuration for stably fixing the main body 100 by increasing the contact area.

In the upper and lower fixtures 300 and 400, the upper fixture 300 is disposed on the upper part based on the upper and lower boundary lines 240, and the lower fixture 400 is disposed on the lower part.

The upper fixture 300 includes an upper bolt 310 coupled to the upper screw 220 of the rotating body 200, an upper plate 320 rotatably coupled to the upper bolt 310, and the upper plate ( It consists of an upper spring 330 coupled to 320.

The lower fixture 400 includes a lower bolt 410 coupled to the lower screw 230 of the rotating body 200, a lower plate 420 coupled to rotate with the lower bolt 410, and the lower plate 420. It consists of a lower spring 430 coupled to.

The upper bolt 310 moves up and down along the longitudinal direction of the rotating body 200 from the inside of the main body 100, and deploys the upper spring 330 to the outside of the main body 100, or retrieved internally.

The upper bolt 310 has a screw thread so that an inner surface is engaged with the upper screw 220, and is moved up and down without rotation according to the rotation of the rotating body 200. The outer diameter of the upper bolt 310 is equal to or slightly smaller than the diameter of the inner circumferential surface 130 of the main body 100 . In addition, the upper bolt 310 may be formed in a polygonal shape.

The inner circumferential surface 130 of the main body 100 is formed in a hexagonal shape according to an embodiment of the present invention, and the upper bolt 310 is also formed in a hexagonal shape. Therefore, when the rotating body 200 rotates forward or backward, the upper bolt 310 is caught on the inner circumferential surface 130 so that rotation is restricted, and the upper screw 220 can move up and down.

Alternatively, by forming a protrusion (not shown) on the outer circumferential surface of the upper bolt 310 and forming a long groove (not shown) in the longitudinal direction on the inner circumferential surface 130 of the main body 100, the protrusion (not shown) is By being inserted into a janghom (not shown), even when the rotating body 200 rotates, the upper bolt 310 may be configured such that the rotation is limited by the protrusion (not shown) and the janghom (not shown) being engaged. If the outer circumferential surface of the upper bolt 310 and the inner circumferential surface 130 of the main body 100 are caught and formed in a structure that restricts the rotation of the upper bolt 310, it is included in the scope of the present invention.

Therefore, since the rotation of the upper bolt 310 is restricted, it is configured to move up and down along the upper screw 220 without rotating along with the rotation of the rotating body 200 .

A coupling groove 311 is formed on the upper surface of the upper bolt 310 along the circumferential direction. The coupling groove 311 is a groove into which the coupling jaw 321 of the upper plate 320 is inserted, and maintains the coupled state between the upper bolt 310 and the upper plate 320, and the upper plate 320 It helps to rotate in the circumferential direction of the upper bolt 310.

The upper plate 320 is configured to be connected so that the upper spring 330 is fixed and the upper spring 330 is also moved up and down according to the up and down of the upper bolt 310.

The upper plate 320 is formed smaller than the diameter of the upper bolt 310, and does not come into contact with the inner circumferential surface 130 of the main body 100. Therefore, even when the top plate 320 rotates, interference with the inner circumferential surface 130 of the main body 100 does not occur.

The upper spring 330 fixed to the upper plate 320 is configured to stably fix the main body 100 by expanding and expanding to the outside of the main body 100 to increase the contact area with the ground.

The upper spring 330 is shown as a single configuration on the drawings according to an embodiment of the present invention, but is not limited thereto and may be provided in plurality. When the upper spring 330 is provided in plurality, the lower end and the upper end are disposed at the same height, and are spaced apart from each other at equal intervals along the circumferential direction of the upper plate 320 .

The upper spring 330 is disposed along the outer periphery of the rotating body 200 while being accommodated inside the main body 100 . When accommodated inside the main body 100, the upper spring 330 is bent to form a smaller diameter than the previously formed diameter while contacting the inner circumferential surface 130 of the main body 100 and It is supported and stores elastic forces inside. When pulled out to the ground through the outlet 140, the upper spring 330 increases to its original diameter while releasing elastic force.

The upper spring 330 penetrates the ground spirally while being drawn out to the ground through the outlet 140 . In addition, as the elastic force is released while coming out of the main body 100, it is formed in a spiral shape gradually drawing a larger diameter, and the contact area with the ground is increased.

As a result, as the upper spring 330 is withdrawn to the outside of the main body 100, a void in the ground does not occur, maintaining the density of the ground, and the outer surface of the upper spring 330 is in contact with the ground to be supported more firmly. can In addition, since the upper spring 330 is pulled out so that its diameter gradually increases, the contact area in the lateral direction increases, so that it can more firmly support the vertical force caused by the load applied from the structure.

The lower fixture 400 is composed of a lower bolt 410, a lower plate 420 and a lower spring 430. As described above, the lower bolt 410, the lower plate 420, and the lower spring 430 have the same structure and operation as the upper bolt 310, the upper plate 320, and the upper spring 330, so a detailed description will be given. omit

Hereinafter, with reference to FIGS. 1 to 4, an operating structure of an embodiment of the underground fixed pile of the present invention will be described.

The underground fixed pile of the present invention is a pile inserted and installed in the ground to reinforce the ground prior to constructing the structure and to stably support the structure.

The main body 100 is inserted deep into the ground and fixed, and the rotating body 200 is rotated forward using the rotating device 500. The rotating device 500 is formed as a handle handle so that an operator can rotate it manually or by using the power of heavy equipment.

As the rotation body 200 rotates forward, the upper fixture 300 rises along the upper screw 220. Looking at this in detail, while the rotating body 200 rotates, the upper bolt 310 also tries to rotate, but is in contact with the inner circumferential surface 130 of the main body 100 and the rotation is limited. Accordingly, the upper bolt 310 rises upward along the thread of the upper screw 220 .

As the upper bolt 310 rises, the upper plate 320 also rises, and the upper spring 330 coupled to the upper plate 320 moves the outlet 140 obliquely along the incline to the outside of the main body 100. As it is drawn out, the upper plate 320 rotates in the circumferential direction of the upper bolt 310.

The upper spring 330 is compressed and received inside the main body 100 to form a diameter smaller than the original diameter, and when it is deployed to the outside through the outlet 140, the elastic force (compression force) is released and gradually returns to the original diameter. expands to

The upper spring 330 extends upward while penetrating the ground in a spiral direction, and further strengthens the bearing capacity of the main body 100 without hindering the density of the ground around the main body 100. In addition, since the diameter gradually expands and develops in the transverse direction, the vertical load transmitted from the structure can be more firmly supported.

Operation of the lower fixture 400 during forward rotation of the rotating body 200 is similar to the operation of the upper fixture 300 described above, but since only the lifting direction acts in the opposite direction, a detailed description will be omitted.

As the rotating body 200 rotates forward, the upper fixture 300 rises and the lower fixture 400 descends, so they rise and fall in a direction away from each other. The upper spring 330 is deployed and expanded to the outside of the main body 100 while going up, and the lower spring 430 is deployed and expanded to the outside of the main body 100 while going down. Therefore, since the diameter formed by the upper and lower springs 330 and 430 is larger than the diameter formed by the main body 100, the contact area with the ground can be increased, and the main body 100 can be fixed to the ground more stably. can

The reverse rotation of the rotating body 200 is performed to recover the upper and lower springs 330 and 430 deployed and extended in the ground to the inside of the main body 100.

When the rotating body 200 reversely rotates, the upper bolt 310 tries to rotate along the upper screw 220 but is caught with the inner circumferential surface 130 of the main body 100 and descends along the screw thread of the upper screw 220. .

As the upper bolt 310 descends, the upper plate 320 is pulled, and the upper spring 330 coupled to the upper plate 320 also flows into and recovers the inside of the main body 100 through the outlet 140. do.

The upper spring 330 is compressed to be smaller than its original diameter inside the main body 100 while moving in a spiral manner.

The operation of the lower fixture 400 during reverse rotation of the rotating body 200 is the same as the operation of the upper fixture 300 described above, but operates in the opposite direction only in the lifting direction.

When the rotating body 200 rotates in reverse, the upper and lower fixtures 300 and 400 are raised and lowered in a direction closer to each other, and the upper and lower springs 330 and 430 are accommodated inside the main body 100. Therefore, since the upper and lower springs 330 and 430 firmly supporting the main body 100 in the ground have been removed, the main body 100 can be easily removed from the ground.

In the underground fixing pile of the present invention, the upper and lower springs 330 and 430 are deployed in opposite directions only by the forward rotation of the rotating body 200, and the diameter is expanded, so that the fixing force of the main body 100 in the ground is further strengthened. There are advantages.

In addition, since the upper and lower springs 330 and 430 expand in a spiral shape when deployed in the ground, the density of the surrounding ground is not disturbed, so that the main body 100 and the upper and lower springs 330 and 430 can sufficiently contact the ground. can strengthen the support.

In addition, when the main body 100 is removed from the ground, the rotating body 200 is rotated in reverse so that the upper and lower springs 330 and 430 are recovered from the ground to the inside of the main body 100 to release the fixation in the ground. It can be easily and conveniently removed.

100: main body 110: tip 120: body head 130: inner circumference 140: outlet
200: rotating body 210: rotating groove 220: upper screw 230: lower screw 240: upper and lower boundary line
300: upper fixture 310: upper bolt 311: coupling groove 320: upper plate 321: coupling jaw
330: upper spring
400: lower fixture 410: lower bolt 420: lower plate 430: lower spring
500: Rotator

Claims (5)

In the pile inserted into the ground and fixed,
A main body 100 having a pointed tip 110 at the lower end, a hollow interior, an open upper end communicating with the inside, and an outlet 140 penetrating the inside and outside;
It is inserted into the inside of the main body 100, a lower screw 230 wound in a certain direction is formed at the bottom, and an upper screw 220 wound in a direction opposite to the direction of the lower screw 230 is the lower screw ( 230) the rotating body 200 formed on the top;
An upper bolt 310 that moves up and down along the upper screw 220 is provided, and an upper plate 320 formed with a smaller diameter than the size of the upper bolt 310 is rotatably coupled to the upper bolt 310. And, one end is coupled to the upper plate 320 and the upper fixture 300 is provided with an upper spring 330 surrounding the outer periphery of the rotating body 200; and
A lower bolt 410 that moves up and down along the lower screw 230 is provided, and a lower plate 420 formed with a smaller diameter than the size of the lower bolt 410 is rotatably coupled to the lower bolt 410, , a lower fixture 400 having one end coupled to the lower plate 420 and having a lower spring 430 surrounding the outer periphery of the rotating body 200;
underground fixing piles.
According to claim 1,
The upper spring 330 and the lower spring 430 are drawn out of the main body 100 through the outlet 140 and are expanded to gradually increase in diameter by elastic force.
underground fixing piles.
According to claim 1,
The upper bolt 310 and the lower bolt 410 are in contact with the inner circumferential surface 130 of the main body 100,
Elevating without rotation along the longitudinal direction of the rotating body 200
underground fixing piles.
According to claim 1,
At the time of forward rotation of the rotating body 200
The upper fixture 300 and the lower fixture 400 are lifted apart from each other,
The upper spring 330 and the lower spring 430 are drawn out of the main body 100 through the outlet 140.
underground fixing piles.
According to claim 1,
At the time of reverse rotation of the rotating body 200
The upper fixture 300 and the lower fixture 400 are lifted so as to be closer to each other,
The upper spring 330 and the lower spring 430 are accommodated inside the main body 100
underground fixing piles.