KR102621201B1 - Pile For Reinforcing Ground - Google Patents

Abstract

The present invention relates to soft ground reinforcement piles for installing solar and wind power generator post structures.
More specifically, in order to fix and install the post structure on soft ground, a spiral wing pile is inserted into the ground, a tube is attached to this and moves mortar, and is provided at the bottom of the tube to inject mortar into the ground through an external injection port. It consists of a lower fixing part that is inserted.
In addition, incision grooves are made on the surface of the spiral wing, and the upper body is bent upward. In the upper body, a hole corresponding to the tube is provided as a tube fixing groove, and the tube is inserted and fixed there. Also, a tube fixing groove (h121) is formed on the lower body side.

Description

Soft ground reinforcement pile for installation of solar and wind power generator post structures {Pile For Reinforcing Ground}

The present invention relates to soft ground reinforcement piles for installing solar and wind power generator post structures. Spiral Bolt For Ground Reinforcemen is used in the construction and installation of natural power generators such as solar power generators and wind power generators, as well as various structures and facilities in civil engineering buildings, by using tubes for injecting mortar to reinforce soft ground. For this purpose, piles to reinforce the bearing capacity of the ground are used.

More specifically, if it is a fill ground that contains gravel or is insufficiently compacted, rather than a hard ground of sandy or clay type, it is considered a soft ground. It is soft ground using piles to reinforce the bearing capacity of the ground to fix and install post structures on such soft ground. This relates to the bearing capacity reinforcement piles used in the ground reinforcement method, and is about a configuration for smartly and highly efficiently injecting mortar by installing a tube in the ground bearing capacity reinforcement piles.

As a method to strengthen the bearing capacity of the soft ground, there is a method of inserting a pile to reinforce the ground and then injecting additional mortar. In the case of rocky ground such as a rock layer or ground containing a large gravel layer, an excavator is used. The rocky ground is excavated, a pile to reinforce the bearing capacity of the ground is inserted into the excavation hole, and then mortar is poured.

Previously published patent number 7943 (January 21, 2016) is shown in Figure 1. The ground bearing capacity reinforcement pile 100 includes a fuselage 110 and spiral wings 120 extending vertically downward from the bottom of the fuselage 110. The fuselage 110 has a cylindrical shape with a through hole 114 inside, and a mounting plate 112 is provided at the top. The mounting plate 112 is intended to be coupled to the flange portion 20 provided at the bottom of the post structure 10, and a plurality of bolt grooves 116 are provided in the circumferential direction for bolt connection. The spiral wing 120 has a structure in which a plurality of unit spiral parts 122 are repeated to increase ground bearing capacity. The spiral wing 120 is formed by twisting the central part of the flat iron, which is the base material, at a certain angle with respect to the central axis in the longitudinal direction to a certain length, so that the unit spiral part is continuous.

The tube 130 is inserted into the through hole 114 of the fuselage 110, passes through the through hole 114, and then is installed to extend to the bottom of the spiral wing 120. A hole penetrates the inside of the tube 130, and mortar is injected into the ground through this hole. The tube 130 may be made of a soft synthetic resin material. The tube 130 is fixed to contact the spiral wing 120, that is, the unit spiral portion 122, by a plurality of fixing parts 140, and the tube 130 is fixed by an appropriate number of fixing parts 140. It is fixed without being separated from the spiral wing (120). The fixing part 140 is usually applied with an adhesive material to fix the tube 130 to the surface of the unit spiral part 122, or the tube 130 is fixed to the unit spiral part 122 through another type of fixing member. ) can be fixed to the surface. In the soft ground reinforcement method using the ground bearing capacity reinforcement pile 100 having this configuration, first, once the location where the post structure 10 is installed is determined, the ground bearing capacity reinforcement pile is installed in the soft ground 150 at that location. (100) is inserted (S210).

Mortar is injected into the tube 130 of the ground bearing capacity reinforcement pile 100 so that the mortar is injected into the ground (S220). As shown, when the ground bearing capacity reinforcement pile 100 is inserted, a portion of the upper part of the body 110 of the ground bearing capacity reinforcement pile 100 is exposed to the ground, and the upper end of the tube 130 is located on the upper part of the body 110. It protrudes, and mortar is injected from the top of this tube 130. Since the hole in the tube 130 is relatively small, mortar is injected into the tube 130 using a pressurizing device (not shown). When mortar is injected in this way, mortar 160 comes out from the bottom of the tube 130 in the ground, and the mortar permeates into the soft ground 150 with many gaps. Once mortar injection is completed, the post structure 10 and the ground bearing capacity reinforcement pile 100 are coupled (fixed) with bolts, etc. In this way, a tube can be installed on the ground's bearing capacity reinforcement pile and through this, mortar can be injected into the soft ground, thereby reinforcing the bearing capacity of the soft ground, ultimately stably fixing the post structure to the soft ground in an easy and quick manner. Can be installed.

Inserting the ground bearing capacity reinforcement pile 100 into the soft ground while exposing a portion of the upper part of the body 110 of the ground bearing capacity reinforcement pile to the ground; Injecting mortar from the top of the tube 130 exposed at the top of the fuselage 110, causing the mortar to come out from the bottom of the tube 130, and injecting the mortar into soft ground; A step of coupling and fixing the post structure to the bearing capacity reinforcement pile 100 of the ground; It is done based on the soft ground reinforcement method using piles to reinforce the bearing capacity of the ground.

The ground bearing capacity reinforcement pile 100 includes a body 110 having a through hole 114 therein and a mounting plate 112 coupled to the post structure 10 at the top; Spiral wings 120 extending downward from the bottom of the fuselage 110 and having a plurality of unit spiral parts 122 to increase the bearing capacity of the ground; A tube 130 installed through the fixing part 140 to be inserted into the through hole 114 of the fuselage 110, pass through the through hole 114, and then extend to the bottom of the spiral wing 120; It is done including. The fixing part 140 is divided into a lower fixing part 141 that fixes the bottom of the tube 130 and a body fixing part 142 that fixes the body of the tube 130. The body fixing part 142 is provided with at least one body fixing part 142 (142-1); Second body fixing part 142 (142-2); It is illustrated as a plurality of third body fixing parts 142 (142-3).

In soft ground where the ground is not hard enough to support the post structure, simple ground bearing capacity reinforcement piles alone do not provide sufficient bearing capacity, and when only the ground bearing capacity reinforcement piles are rotated and inserted into the ground without drilling a separate excavation hole in advance, mortar is used. Since it is not easy to insert a bearing capacity reinforcement pile into soft ground, a technology is required to reinforce the ground by evenly injecting mortar around the body of the pile where the tube is installed, and spiral wings ( It is desirable that mortar can also be injected into the opposite side to which the lower fixing part 141 of 120) is attached.

As a soft ground reinforcement pile for installing solar and wind power generator post structures,

It has a fuselage having a through hole therein, and spiral wings extending downward from the bottom of the fuselage,

It is provided with a tube through which mortar moves after passing through the through hole and extending to the bottom of the spiral blade, and a cylindrical lower fixing part formed at the bottom of the tube to inject mortar into the ground through an external inlet. ,

The inner periphery of the lower fixing part takes the shape of a cylinder, and a piston is mounted vertically up and down corresponding to it,

An H-shaped cutting groove is formed on the surface of the spiral wing, the upper body of the upper part formed by the cutting groove is bent upward, and the lower body of the lower part is bent downward, but at an acute angle (r1). It is bent, and the opposite side becomes an obtuse angle, providing less resistance from the soil.

A tube fixing groove corresponding to the outer shape of the tube is formed in the upper body, and the tube is inserted and fixed into the tube fixing groove, so that mortar can be introduced from the side opposite to where the lower fixing part is attached,

The tube fixing groove is additionally formed on the lower body side of the lower portion, so that the bottom of the tube is interposed and firmly fixed.

According to the soft ground reinforcement pile for the installation of solar and wind power generator post structures, mortar can be injected on the opposite side where the lower fixing part of the spiral blade is attached. After inserting the bearing capacity reinforcement pile, the ground bearing capacity reinforcement pile is Mortar can be spread widely and evenly around the body, thereby strengthening the bearing capacity of soft ground.

Figure 1 is a front view of the ground bearing capacity reinforcement pile and related configuration, and a state diagram of an example in which the ground bearing capacity reinforcement pile is constructed in soft ground.
2A of FIG. 2 is an enlarged cross-sectional view of a portion. Figure 2B example is an operational state diagram. Figures 2C and 2D, shown in cross-sectional perspective, illustrate the configuration and operating conditions of another embodiment.
Figure 3 shows one embodiment of the present invention.
4 to 7 show another embodiment of the present invention.

Typically, the ground bearing capacity reinforcement pile 100 for reinforcing soft ground includes a body having a through hole inside and a mounting plate coupled to the post structure at the top, and spiral wings 120 extending downward from the bottom of the body. It is provided with a tube 130 that is inserted into the through hole of the fuselage and extends to the bottom of the spiral wing 120 after passing through the through hole, and is attached to the spiral wing 120 when installing the tube. A fixing part 140 is provided so that the tube is firmly attached to the spiral wing 120, so that when mortar is injected from the top of the tube, the mortar moves downward along the tube and the mortar is injected into the soft ground at the bottom of the tube. See Figure 2.

The lower end of the tube 130 has a tube bottom outlet 130a through which mortar is discharged, and the fixing part includes a cylindrical lower fixing part 141 for fixing the lower end of the tube, and the upper end of the lower fixing part 141 is the lower part of the tube. A tube lower fixing inlet (141e) is formed having an inner periphery corresponding to the outer periphery of the outlet (130a), the lower end (141d) of the lower fixing part (141) is blocked, and the body periphery of the lower fixing part (141) is formed. The perforated opening is partially formed and used as the external inlet (141a) of the lower fixing part (141). The inner periphery of the lower fixing part 141 takes a cylindrical shape, and correspondingly, a piston 141c which takes a cylindrical shape vertically up and down is mounted, and the outer periphery of the piston 141c is that of the lower fixing part 141. It goes up and down by sliding while in close contact with the inner surroundings, and normally closes the external inlet (141a) of the lower fixing part (141), so that the vertical length of the piston (141c) is outside of the lower fixing part (141). It is taken to be longer than the vertical length of the injection port 141a, and the lower space 141b of the lower fixing part 141 has a vertical length so that it can completely accommodate the piston 141c when it descends and reaches the lowest point position. When mortar is injected from the tube bottom outlet 130a into the interior of the lower fixing part 141 by taking it larger than the vertical length of the piston 141c, the pressure first lowers the piston 141c, and accordingly, the lower end height The external injection port 141a of the top 141 is opened to the outside and mortar is injected into the soft ground.

The tube is fixed to the spiral wing 120 through a plurality of body fixing parts 142, and the tube 130 is provided with the middle and middle of the body separated, and the body fixing part 142 is in the form of a pipe with an empty interior. By taking, each separate entrance of the tube 130 is configured to be fixed to each of the upper and lower entrances of the body fixing part 142, and the body fixing part ( 142) is provided with an external inlet 141a of the body fixing part 142, which is formed by opening a certain portion around the body, and the external inlet 141a of the body fixing part 142 is a blocking film that is normally kept in a blocked state. It is provided with (142a`), and the barrier film (142a`) is selected as a member that can be destroyed when the load pressure exceeds the set before construction, so that the external inlet (141a) of the lower fixing part (141) is opened and the mortar is externally weak. When the mortar is injected (m4) into the ground, the mortar flows smoothly downward, reaches the external injection port (141a) of the lower fixing part (141), and flows out. Afterwards, when the soft ground on the side of the lower fixing part 141 is compacted and the mortar can no longer escape, the internal pressure of the tube 130 increases, and accordingly, the internal pressure is applied to the blocking film 142a'. It operates on the principle that the barrier film (142a') is destroyed and the external inlet (141a) of the body fixing part (142) is opened and mortar is injected into the soft ground around it. The plurality of body fixing units 142 include the first body fixing unit 142 (142-1); Second body fixing part 142 (142-2); and a third body fixing part 142 (142-3), each of which includes an external inlet 141a and a blocking film 142a' of the body fixing part 142, and each blocking film 142a is sequentially provided. The rupture strength of `) is set differently, so that the external inlet 141a of the body fixing part 142 is sequentially opened in such a way that the barrier film 142a` ruptures from the bottom to the top, gradually starting from deep in the ground. It is designed to compact and reinforce soft ground by injecting mortar into the shallow area. Through this, the area where mortar is injected into soft ground can be prevented from clogging, and thus mortar can be injected into soft ground more smoothly.

According to the bearing capacity reinforcement pile for soft ground reinforcement according to FIG. 2, when mortar is injected into the surrounding soft ground, the external injection port of the lower fixing part 141 is formed by the spiral wing 120, that is, the unit spiral part 122. (141a) Since one side is blocked and blocked, it is not easy to spray mortar in that direction, so let's look at a smarter pile for reinforcing soft ground.

The bearing capacity reinforcement pile is configured with a means 100 that allows mortar to be sprayed (s2) on the lower side of the spiral wing 120 to the side opposite to the side where the lower fixing part 141 of the tube 130 is attached. Meanwhile, all grooves or cutting grooves can be achieved through laser cutting or press processing.

As an example in FIG. 3, this is achieved by forming a mortar outflow hole (h110) formed by making a groove (drilling a hole) on the lower side of the spiral wing 120 with the mortar spraying means 100 on the side opposite to the attachment of the tube 130. can do. Through this, the mortar is configured to pass through the mortar outflow hole (h100) and be sprayed (s2) on the side opposite to where the tube 130 is attached. Figure 3A shows an exploded view of the spiral wing 120 and the tube 130 with the mortar outflow hole (h100), Figure 3B shows the combined view, and Figure 3C shows this side of the spiral wing 120 ( s1) Indicates a state in which mortar is sprayed to the other side (s2), that is, the mortar is sprayed to both the side to which the tube 130 is attached and the opposite side to which the tube 130 is attached.

4 to 7, as a means 100 for spraying mortar to the opposite side of the tube 130, a mortar outflow and tube fixing bracket 120 integrated with a spiral wing 120 are formed, and the mortar outflow is integrated here. A hole (h0) (which can be replaced by ‘mortar outflow groove’ to distinguish it from the one in the embodiment of Figure 3 A) is formed (perforated) at the same time. Looking in more detail, in Figure 4, the incision grooves (h1, h2) cut (cut) in an H shape on the surface of the spiral wing 120 are dented, so that the spiral wing 120 can be separated or removed from the body. Therefore, as shown in Figure 5, the non-cut portions (h3) that are not cut at the top and bottom can be bent (bended, bent, bent) at right angles (or at acute or obtuse angles) up and down, respectively, around the bending axis. In this way, an integrated mortar outflow and tube fixing bracket 120 is formed. The example on the right in Figure 5 shows a bent state from the side, and can be better explained through the example in the oval box below Figure 5.

In addition, on the side of the bracket upper body (h122), which is the upper part of the body of the integrated mortar outflow and tube fixing bracket 120 cut in an H shape, a groove (hole) corresponding to the outer periphery (outer shape) of the tube 130 is hollowed out (perforated). ) is provided as a tube fixing groove (h121). As shown in Figure 6, the tube 130 can be inserted (interposed) into the tube fixing groove (h121) and fixed very firmly. In addition, the tube fixing groove (h121) can be formed by adding it to the bracket lower body (h123), which is the lower part of the body cut in the shape of H, and then fixed more firmly by interposing a predetermined portion of the bottom of the tube 130. Mortar is sprayed (flowed, discharged) through the mortar outlet hole (h0).

As described above, in the embodiment of FIGS. 5 and 6, the upper body (h122), which is formed by cutting the H-shaped cutting grooves (h1, h2), is bent upward at a right angle, and the lower body (h123) of the lower part is bent upward. ) is bent downward and at a right angle to form an integrated mortar outflow and tube fixing bracket 120. Meanwhile, in the embodiment of FIG. 7, the lower body (h123) is bent (bent) downward at an acute angle of a predetermined angle (r1) that is less than a right angle, so that the opposite side becomes an obtuse angle (r1 < r2). Through this, in particular, when the bottom fixing part 141 at the bottom of the tube 130 penetrates the ground along the spiral wing 120 and descends into the ground, it receives less resistance from the soil to reduce friction.

Ground bearing capacity reinforcement pile (100); tube 130; Fixing part 140; Tube fixing groove (h121); Spiral wings (120); Bottom fixing part (141); External inlet (141a) of the lower fixing part (141); Tube bottom fixed entrance (141e);

Claims (1)

As a soft ground reinforcement pile for installing solar and wind power generator post structures,
It has a fuselage having a through hole therein, and spiral wings extending downward from the bottom of the fuselage,
It is provided with a tube through which mortar moves after passing through the through hole and extending to the bottom of the spiral blade, and a cylindrical lower fixing part formed at the bottom of the tube to inject mortar into the ground through an external inlet. ,
The inner periphery of the lower fixing part takes the shape of a cylinder, and a piston is mounted vertically up and down corresponding to it,
An H-shaped cutting groove is formed on the surface of the spiral wing, the upper body of the upper part formed by the cutting groove is bent upward, and the lower body of the lower part is bent downward, but at an acute angle (r1). It is bent, and the opposite side becomes an obtuse angle, providing less resistance from the soil.
A tube fixing groove corresponding to the outer shape of the tube is formed in the upper body, and the tube is inserted and fixed into the tube fixing groove, so that mortar can be introduced from the side opposite to where the lower fixing part is attached,
The tube fixing groove is further formed on the lower body side of the lower part formed by the H-shaped cut groove, so that the bottom of the tube is interposed and firmly fixed.
Soft ground reinforcement pile for installation of solar and wind power generator post structures .