KR102060114B1 - A Underground Structure - Google Patents

Abstract

The present invention relates to an underground structure for reinforcing the binding of soil, which reinforces an underground binding force by being constructed in soft ground such as a slope or soil and, more specifically, to an underground structure for reinforcing the binding of soil, which comprises: a main support constructed by being driven into the ground; a rotary screw shaft inserted and installed in the main support to be able to rotate; a slider vertically moved by the rotation of the rotary screw shaft; and an auxiliary support inserted and installed in a body portion of the main support. While the slide is lowered by the rotation of the rotary screw shaft, the auxiliary support is configured protrude to the outside of the main support so that the underground structure is constructed by being driven into the ground. Therefore, the underground structure prevents subsidence of a slope by dramatically reinforcing the underground binding force of the slope or soil (flatland) and prevents loss and collapse of the soil, thereby stabilizing unstable soft ground.

Description

A Underground Structure for Strengthening Soil Bonds

The present invention relates to an underground structure for reinforcing ground cohesion by constructing on a soft ground such as a slope or soil, and more specifically, a main support body which is driven into the ground and constructed to be rotated so as to be rotated inside the main support body. Consists of a screw shaft, a slider that is moved up and down by the rotation of the rotation screw shaft, and an auxiliary support body inserted into the main body of the main support body, and the auxiliary support body protrudes outward from the main support body while the slider is lowered by the rotation of the rotation screw axis. The ground binding force of the soil structure for strengthening the soil binding to stabilize the unstable soft ground by preventing the ground settlement of the slope and preventing the ground subsidence of the slope by dramatically strengthening the ground binding force of the slope or soil (flat) will be.

Since the soil surface is exposed to the outside on the slopes of mountains, roads, rivers, parks, or dwellings, the soil is leaked due to the effects of rainy weather or wind and the erosion is accelerated. Due to such erosion, landslides and floods frequently occur during rainy weather, causing many casualties.

To prevent this, concrete walls and retaining walls are constructed. These retaining walls form formwork with rebars and panels to cut soils in construction areas or fill valleys and lower areas in mountainous areas.

Then, the concrete is poured into the form and the ground is filled with soil and crushed stone is generally constructed.

The retaining wall of the reinforced concrete can prevent erosion to some extent, but it is not aesthetically pleasing, and the concrete retaining wall is not preferable in terms of cost and air due to molding and curing, and also has a disadvantage of costly construction. have.

In order to solve this problem to some extent, through the Republic of Korea Utility Model Publication No. 20-0359071, when the pile is embedded in the ground, it has a structure that can be installed in the form of tree roots to support the support of the ground Tree rooted piles are known.

In addition, the prior art 'ground binding type pile' of the Republic of Korea Patent No. 10-1527432 is known.

The conventional ground-binding pile is convenient to use as a fixing pile such as a tent when camping, but it is somewhat unreasonable to use for ground reinforcement of inclined ground.

KR 20-0359071 (registration number) 2004.08.05. KR 10-1527492 (registration number) 2015.06.03. KR 10-1017534 (registration number) 2011.02.26.

Accordingly, the present invention has been made to solve the above conventional problems,

It consists of the main support body installed on the sloped ground, the rotating screw shaft inserted and installed to rotate inside the main support body, the slider moved up and down by the rotation of the rotating screw shaft, and the auxiliary support body inserted into the body of the main support body. As the slider descends by the rotation of the rotating screw shaft, the auxiliary supporting body protrudes to the outside of the main supporting body and is driven into the ground, thereby significantly strengthening the ground binding force such as the inclined surface to prevent settlement of the soft ground, and to prevent the loss of the inclined surface. The purpose is to provide a soil structure for strengthening soil binding that prevents collapse and stabilizes unstable ground.

Another object of the present invention is to install a plurality of auxiliary support to be inserted into the body of the main support in the upper and lower multi-stage at regular intervals along the circumferential direction and to install the inside of the main support to the outer surface of the main support main body According to the descending slider to be able to construct quickly to improve the work efficiency.

Another object of the present invention is to be able to extend the construction range for the place where the ground support force is required, such as the support of the tent or the holding of the safety rail by installing the auxiliary support to the ground so that it does not fall well by driving into the ground. .

In order to achieve the above object, the present invention is constructed on an inclined ground surface or a soft ground to enhance the ground binding force, and the main support body 110 is built to strengthen the ground binding force by being driven into the inclined plane of the river or the cut surface of the road. )and; A rotating screw shaft (120) installed to be rotatable from an inner center upper end portion to a lower end portion of the main support body (110) and having a thread (120a) formed on an outer surface thereof; Auxiliary support body 130 is provided in the body portion of the main support body 110 inclined downward in the circumferential direction is inserted into the ground; And a slider which is screwed to the rotation screw shaft 120 installed inside the main support body 110 and moves from the inner upper portion to the lower portion of the main support body 110 according to the rotation of the rotation screw shaft 120. 140, including;

The main support body 110 is installed to be divided and fastened along a longitudinal direction to a plurality of body parts 111, the slider 140 is movable between the body parts 111. It is formed as a passage portion 112 to be spaced apart from each other, the auxiliary support 130 is inserted into the upper and lower multi-layer inclined downward in the passage portion 112, the slider 140 is the passage portion 112 Pressing the auxiliary support body 130 while descending according to the configuration characterized in that the construction is installed in the ground as they protrude to the outside of the main support body (110).

In addition, the slider 140 of the present invention is the central portion 141 is screwed to the rotation screw shaft 120 to move up and down in the rotation of the rotation screw shaft 120, and the circumferential direction toward the side of the central portion 141 It is provided with a plurality of protruding along the bottom portion (a) and the vertical surface portion (b) and the inclined triangle portion 142 consisting of the inclined surface portion (c), the bottom portion (a) is the upper end and the inclined surface portion ( c) is positioned so as to be located in the passage portion 112 of the separating body portion 111, the width thereof becomes smaller gradually toward the lower portion.

In addition, the wall portion of the divided body portion 111 constituting the main support body 110 of the present invention is provided with a multi-layer groove portion 111a is inserted into the auxiliary support body 130 so as to be slidable. The cover flange 111b is formed on one side of the corner portion along the longitudinal direction of the divided body portion 111 to connect and fix the divided body portion 111 while blocking the passage part 112. The cover flange 111b is provided with a discharge port 111h through which the auxiliary support body 130 protrudes outward.

In addition, the auxiliary supporting body 130 of the present invention is inserted into the passage portion 112, the side portion of the body portion 131 is supported by being seated in the groove portion 111a formed in the partition body portion 111 And a wing portion 132 protruding from the side portion of the body portion 131 and inserted into the slot 111c formed in the recess 111a to be slidable.

In addition, the head projection to be located in the passage portion 112 in the upper surface portion of the body portion 131 of the auxiliary support body 130 of the present invention so that the auxiliary support body 130 does not escape to the discharge port 111h. 133 is further provided.

In addition, at the end of the groove portion 111a formed in the divided body portion 111 of the present invention, a seating recess 111d is further formed to support the top end of the auxiliary support 130.

The soil structure for strengthening the soil binding of the present invention is projected to the outside of the main support body by protruding the auxiliary support body inserted into the body of the main support body while the slider descends by the rotation of the rotation screw shaft provided inside the main support body. By constructing, the ground bond strength of the slope is greatly strengthened to prevent settlement of the soft ground and to stabilize the unstable ground by preventing the loss and collapse of the slope.

In addition, the present invention is installed in the upper and lower multi-stage subsidiary support body is inserted into the body portion of the main support body is installed a plurality of at regular intervals along the circumferential direction and descending along the inside of the main support body to the outer surface of the main support body The work efficiency is improved by allowing the construction to be performed quickly by the slider.

In addition, the present invention is the convenience of work by projecting the auxiliary support body inserted into the main support body to the outside of the main support body while the slider is lowered by the rotation of the rotation screw shaft provided in the main support body to drive in the ground. This is improved.

In addition, the present invention can be used in the place where the ground support force is required, such as the support of the tent or the support of the safety rail by installing the main support into the ground and the secondary support is installed in the ground at the lower end of the advantage that the utility range is extended There is also.

In addition, the present invention can reduce the construction time by the construction of a rigid holding body on the slope of the slope or the soft ground to prevent ground subsidence, there is also the effect of reducing the cost of installation is simple.

1 is a cross-sectional view of the soil structure for strengthening the soil binding according to the present invention is built into the ground of the slope,
Figure 2 is a schematic perspective state view of the soil structure for strengthening soil binding according to the present invention,
Figure 3 is a schematic separated perspective view of the soil structure for strengthening soil binding according to the present invention,
Figure 4 is a schematic cross-sectional view of the soil structure for strengthening soil binding according to the present invention,
Figure 5 is a cutaway state cross-sectional view of the soil structure for strengthening soil binding according to the present invention,
Figure 6 is a plan view of the main support body and soil supporting state of the soil structure for strengthening the soil binding according to the invention,
Figure 7 is a construction procedure state diagram is installed on the inclined surface soil structure for strengthening soil binding according to the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described to be easily carried out by those of ordinary skill in the art.

As shown in FIGS. 1 to 7, the soil structure for strengthening soil binding according to the present invention is illustrated in FIGS. 1 to 7.

A main support body 110 which is constructed to prevent ground subsidence and to strengthen the ground binding force by being driven into an incline or a soft ground of a river;

Rotating screw shaft 120 is installed to be rotatable from the upper end of the inner center to the lower end of the main support body 110 and the thread 120a is formed on the outer surface

Auxiliary support body 130 is provided in the body portion of the main support body 110 inclined downward in the circumferential direction is inserted into the ground; And

A slider which is screwed to the rotation screw shaft 120 installed inside the main support body 110 and is movable from the inner upper side to the bottom of the main support body 110 according to the rotation of the rotation screw shaft 120. 140, including;

The main support body 110 is installed to be divided and fastened along the longitudinal direction to a plurality of partition body portion 111, between the partition body portion 111 between each other so that the slider 140 is lowered. A spaced passage portion 112 is formed,

The auxiliary support body 130 is inserted into the upper and lower multilayers to be inclined downward in the passage part 112, and the slider 140 presses the auxiliary support body 130 while descending along the passage part 112. They are characterized in that the construction is installed in the ground while protruding to the outside of the main support body (110).

In general, the cut surface formed in rivers, parks, etc. is exposed to the outside by construction, so soil is easily eroded and collapsed due to the effects of rain or wind. many.

However, concrete construction has a problem that it is not only expensive, but also difficult and time-consuming to construct.

In order to solve this problem, conventionally, the construction method is applied to the strut body at regular intervals on the inclined surface with a simple and low cost to connect them from the outer surface.

However, the conventional struts or struts are simply configured to be fixed to the slope of the slope or the soil, so that the supporting force and the binding force on the slope or the soil are weak.

Therefore, the present invention is applied to the main holding body 110 by applying a force (F) to the inclined plane of the incision plane, such as driving, and then rotates the rotating screw shaft 120 when the slider 140 is screwed to this The main support body 110 is lowered along the passage part 112 formed between the divided body parts 111, and the auxiliary support body 130 installed downwardly inclined downward in the passage part 112 is pressed. Protruding to the outside of the) will be embedded into the ground and installed.

At this time, the auxiliary support 130 of the present invention may protrude to the outside of the main support 110, but may be installed in the ground by bending at a right angle (90 degrees) or more with respect to the construction direction of the main support 110. In addition, the auxiliary support 130 may be protruded into the ground in the inclined direction installed.

That is, according to the present invention, after the construction of the main support body into the ground, the secondary support body protrudes into the ground secondly from the main support body, thereby significantly improving the ground bearing force and the binding force of the incision slope or the flat ground. .

As such, the main support body 110 of the present invention is constructed by driving the incision inclined surface or flat surface and the auxiliary support body 130 built in the division body portion 111 of the main support body 110 is the slider ( The projecting force of the main support body 110 is increased by the lowering force of the main support body 110, and the construction of the main support body 110 increases the cohesion force of the incision or the flat ground, thereby improving stability of the soft ground.

The slider 140 of the present invention along the circumferential direction toward the side of the central portion 141 and the central portion 141 which are screwed to the rotating screw shaft 120 to move up and down in the rotation of the rotating screw shaft 120. It is provided with a protruding bottom portion (a) and a vertical triangular portion (b) and the inverted triangular portion 142 consisting of the inclined surface portion (c), the bottom portion (a) is the upper end portion and the inclined surface portion (c) is It is positioned in the passage portion 112 of the division body portion 111 is formed in a shape that the width gradually decreases toward the lower end.

And in the embodiment of the present invention, the main support 110 has a cylindrical shape and each of the divided body portion 111 is divided into four equal parts (90 minutes) at intervals of 90 degrees, and they are connected to each other while being installed The passage part 112 is formed in this structure.

In addition, four sliders 140 are also installed to be respectively inserted into the passage portion 112 formed between the divided body portion 111 divided into four equal parts. That is, four passage portions 112 formed in the main support body 110 are formed in a cross shape with reference to the center of the main support body 110 and are inserted into and installed in the passage part 112. Four sliders 140 are also formed in a cross shape.

However, the main support body 110 may be composed of a square pillar, a triangular pillar or a polygonal pillar of five or more angles. In addition, the divided body portion 111 may be composed of equal parts other than four equal parts. In this case, the slider 140 is also preferably provided in a shape corresponding thereto.

In addition, the wall surface portion of the divided body portion 111 constituting the main support body 110 is provided with a multi-layer groove portion 111a is inserted into the auxiliary support body 130 to be slidable.

Accordingly, one side of the auxiliary support 130 is seated and supported by the recess 111a formed in one division body 111, and the other side of the auxiliary support 130 is the other division body part ( It is seated and supported by the recess 111a formed in the 111.

The recess 111a is formed to form a right angle with the inclined surface portion c of the slider 140. The force applied when the slider 140 is lowered by the rotation of the rotation screw shaft 120 to the inclined surface portion (c) at right angles and the force applied along the inclined surface portion (c) The recess 111a is formed at right angles to the inclined surface portion c so that the auxiliary support 130 is slidably moved by the force applied to the inclined surface portion c at a right angle.

In addition, the cover flange (111b) for connecting and fixing the partition body portion 111 while blocking the passage portion 112 of any one side of the corner portion along the outer side longitudinal direction of the partition body portion 111 is The cover flange 111b is provided with a discharge port 111h through which the auxiliary support 130 protrudes outward.

Here, through the cover flange (111b) a plurality of the divided body portion 111 can be fixed in a single body (cylindrical) shape to each other stably.

That is, forming a recess 111ba in which the end of the cover flange 111b is seated at the corner of the division body 111 and seating the end of the cover flange 111b in the recess 111ba. By fixing with a bolt or welding, the partition body portion 111 is connected and fixed.

Therefore, the auxiliary support 130 is protruded outwardly through the discharge port 111h while being inclined down along the passage part 112 so that it can be constructed in the ground.

In addition, the recess 111 is formed in the divided body portion 111 is further formed with a slot 111c is inserted into the wing of the auxiliary supporting body 130 to be described later sliding.

On the other hand, the auxiliary support 130 is inserted into the passage portion 112 and the side portion of the body portion 131 that is seated and supported by the groove portion 111a formed in the body portion 111 and The protrusion 132 is provided on both side surfaces of the body 131 to be inserted into the slot 111c formed in the recess 111a to be slidable.

In addition, the upper surface portion of the body portion 131 supported by the inclined surface portion (c) of the slider 140 is located in the passage portion 112 and the auxiliary support 130 is completely discharged into the discharge port (111h) The head protrusion 133 may be further formed so as not to go out.

The width of the head protrusion 133 is smaller than the width of the passage part 112.

Therefore, when the slider 140 descends and presses the auxiliary support 130, the auxiliary support 130 has its body 131 and the wing 132 at the divided body 111. Protruding through the discharge port 111 while sliding along the groove 111a and the slot 111c formed in the ground.

In addition, a seating recess 111d may be further formed at an end of the recess 111a formed in the partition body 111 to be supported while the upper end of the auxiliary support 130 is seated.

When the upper end of the auxiliary support 130 is seated in the seating recess 111d, the auxiliary support 130 may be protruded at right angles or more to the outer surface of the main support 110.

In addition, the upper plate 113 protrudes from an upper end of the main screw 110 to protrude from the upper end of the pivot screw shaft 120 so that the pivot screw shaft 120 is not detached. Is provided.

In addition, the lower side of the main support body 110 is provided with a lower support 122 for supporting the end of the rotating screw shaft 120.

Therefore, the rotation screw shaft 120 can be rotated stably in the center of the main support body (110).

The main support body 110 has a main pointed portion (111a) is formed in the lower end of the sub supporter 130a to be well installed in the ground and the sub pointed portion (130a) to be well installed in the end of the auxiliary support body 130 Is formed.

It looks at the procedure of driving the soil binding structure for strengthening the soil binding structure 100 of the present invention configured as described above on the ground.

First, the main support body 110 is applied to the ground by applying a force (F) using a driving machine or the like to the incision plane or flat ground.

Then, the rotating screw shaft 120 is rotated using a T-shaped tool or the like.

As the pivot screw shaft 120 rotates, the slider 140 descends along the passage part 112 formed in the main support body 110.

The auxiliary support 130 provided in the passage portion 112 descends as the slider 140 descends, protrudes outward through the discharge port 111h formed in the main support body 110, and constructs underground. do.

As such, the auxiliary support body 130 protrudes to the outside of the main support body 110 in the state in which the main support body 110 is inserted into the ground, so that the auxiliary support body 130 is like a tree root. ) Will be installed to strengthen the soft ground cohesion of the ground.

As described above, the soil binding reinforcement underground structure according to the present invention is a main support body which is constructed as sloped ground, a rotating screw shaft inserted and installed to be rotated inside the main support body, a slider which is moved up and down by rotation of the rotation screw shaft, It consists of an auxiliary support that is inserted into the main body of the main support.The slider is lowered by the rotation of the rotation screw axis, and the auxiliary support protrudes to the outside of the main support and is driven into the ground, thereby significantly strengthening the underground binding force of the inclined surface. This prevents ground subsidence of the slope and prevents loss and collapse of the slope to stabilize the unstable soft ground.

100: soil structure for strengthening soil binding
110: Main subject
111: Division body portion 111a: Groove portion 111b: Cover flange 111ba: Concave portion
111c: Slot 111d: Settling recess 111h: Outlet 112: Passage part
113: top plate
120: rotating screw shaft 120a: screw thread
121: upper support 122: lower support
130: secondary support
131: body 132: wing 133: head projection
140: slider
141: center portion 142: inverted right triangle
a: Bottom part b: Vertical part c: Inclined part

Claims (6)

In the underground structure that is installed on the inclined slope or soft ground to strengthen the ground binding force,
A main support body 110 which is constructed to be inclined to the inclined plane of the river or the incision of the road to strengthen the ground binding force;
Rotating screw shaft 120 is installed to be rotatable from the upper end of the inner center to the lower end of the main support body 110 and the thread 120a is formed on the outer surface
Auxiliary support body 130 is provided in the body portion of the main support body 110 inclined downward in the circumferential direction is inserted into the ground; And
A slider which is screwed to the rotation screw shaft 120 installed in the main support body 110 and is moved from the inner upper portion to the lower portion of the main support body 110 according to the rotation of the rotation screw shaft 120 ( 140);
The main support body 110 is installed to be divided and fastened along a longitudinal direction to a plurality of body parts 111, the slider 140 is movable between the body parts 111. Is formed as a passage portion 112 to be spaced apart from each other,
The auxiliary support 130 is inserted into the upper and lower multilayers to be inclined downward in the passage part 112, and the slider 140 presses the auxiliary support 130 while descending along the passage part 112. They are installed in the ground while protruding to the outside of the main support body 110,
The wall portion of the divided body portion 111 constituting the main support body 110 is provided with a multi-layer groove portion 111a is inserted into the auxiliary support body 130 so as to be slidable.
A cover flange 111b for connecting and fixing the partition body 111 is formed at one side of the corner portion along the longitudinal direction of the partition body 111 to block the passage part 112. ,
Soil binding reinforcement underground structure is formed in the cover flange 111b is formed with a discharge port (111h) protruding to the outside of the auxiliary supporting body (130).
The method of claim 1,
The slider 140 protrudes along the circumferential direction toward the central portion 141 screwed to the rotation screw shaft 120 and the side surface of the central portion 141 so as to move up and down in the rotation of the rotation screw shaft 120. It is provided with an inverted triangular portion 142 is provided with a bottom portion (a) and a vertical surface portion (b) and the inclined surface portion (c), the bottom portion (a) is the upper end and the inclined surface portion (c) is The soil structure for strengthening the soil binding to be located in the passage portion 112 of the partition body portion 111 is gradually reduced in width toward the lower portion.
delete The method of claim 1,
The auxiliary support 130 is inserted into the passage portion 112 and the side portion is the body portion 131 is supported by being seated in the groove portion (111a) formed in the divided body portion 111 and the A soil structure for strengthening soil binding comprising a wing portion 132 protruding from the side portion of the body portion 131 and inserted into the slot 111c formed in the recess 111a to enable sliding.
The method of claim 4, wherein
In the upper surface portion of the body portion 131 of the auxiliary support 130, the head projection 133 is located in the passage portion 112 to prevent the auxiliary support 130 from escaping to the discharge port 111h. Underground structure for strengthening the soil binding is further provided.
The method of claim 5,
Soil binding reinforcement underground structure is further provided with a seating groove (111d) is formed at the end of the groove portion (111a) formed in the partition body portion 111 is supported by the upper end of the auxiliary support 130.

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