KR101268922B1 - Anchor for spreading loads - Google Patents

Abstract

In a load-distributing anchor having two or more multi-stage anchors for reinforcing soft ground, two or more strand members (100, 102, 104, 106) are introduced through the receiving hole (205), and the shape of the head is inclined to the gradient surface. A plurality of pressing means (200, 202) spaced at predetermined intervals so as to improve the anchoring force by being directly transmitted to the wall of the punched hole by the repulsive force applied to the tension member; Fixing members (300,302) formed on the rear side of each pressing means for fixing the gap of the tension member; A plurality of protective caps 400 formed between the pressing means and the fixing member to accommodate the tension member from one side and the fixing wedge 450 from the other side to fix the end of the tension member through the fixing wedge; A fixing wedge 450 having an inner diameter corresponding to an end diameter of the tension member and having protrusions formed therein to press and fix the outer surface of the tension member; Including, but some of the plurality of tension member is accommodated, fixed to any one of the plurality of protective cap, the remaining tension member is multi-stage characterized in that it has a multi-stage anchor body structure by being accommodated in another protective cap Load distribution anchors are presented.

Description

Anchor for spreading loads

The present invention relates to an anchor used in civil engineering, to a multi-stage load distribution anchor having a structure that can effectively distribute the load applied to the tension member.

The ground anchor method is a method commonly used in earthquake construction or retaining wall reinforcement works. A hole is formed using a perforator in the ground where the anchor is to be installed, and a load-bearing body such as grout hose and tension member (steel wire member) is formed in this hole. After inserting, the grout is injected through the grout hose to combine the inner body and the grout, and to tension the one end of the tension member to reinforce the soft ground.

When the ground anchoring method is applied, it is important that the anchor structure is firmly coupled to the ground by effectively transmitting the repulsive force to the wall of the drilled hole when the anchor is coupled to the other end of the tension member and the tensile force is applied to the tension member.

In the conventional general ground anchor structure, since the shape of the upper end of the anchor body has a flat structure, there is a problem in that the structure does not generate resistance to act perpendicular to the wall of the hole.

In order to solve this problem, in the conventional anchor body, an expansion-type spike structure or an expansion-type projection that is able to penetrate the wall of a hole was used, but such a structure has a problem such as an increase in production cost and an increase in manufacturing time due to its complicated structure.

In addition, the anchor body is installed only at the end of the tension member concentrated tension load was insufficient to reinforce the soft ground with a sense of stability.

In view of the above problems, in the present invention, the anchor body is installed in multiple stages, and a constant gradient is applied to the head of the pressurizing means (means for transmitting force perpendicular to the wall of the hole). By constructing), we propose a groundbreaking multi-stage load distribution anchor that can effectively distribute the load and ensure sufficient ground reinforcement.

In the present invention, an object of the present invention is to provide an anchor structure capable of effectively dispersing an external force applied to a tension member, and to provide a multi-stage anchor body.

In addition, the present invention proposes an innovative load distribution anchor for soft ground reinforcement by forming a pressing means having an inclined gradient surface that can effectively press vertically on the wall of the drilled hole on the anchor body.

The solution means for achieving the above object is as follows.

That is, in the load-distributing anchor having two or more multi-stage anchor bodies for reinforcing soft ground, two or more strands of tension member are introduced through the receiving hole and passed through, and the shape of the head is formed by the inclined gradient surface, A plurality of pressing means spaced apart at predetermined intervals so that the repulsive force against the tensile force applied to the member is directly transmitted to the wall of the hole to improve anchoring force; and,

Fixing members formed on the rear side of each pressing means for fixing the gap of the tension member; Wow,

A plurality of protective caps formed between the pressing means and the fixing member to accommodate the tension member from one side and the fixing wedge from the other side to fix the tension member end through the fixing wedge;

It has an inner diameter corresponding to the end diameter of the tension member, a protrusion is formed therein, fixing wedge for pressing, fixing the outer surface of the tension member;

Some of the plurality of tension members are accommodated and fixed in any one of the plurality of protective caps, and the remaining tension members are accommodated in another protective cap to have a multi-stage anchoring structure characterized in that it has a multi-stage anchor body structure. Is presented.

The gradient surface of the pressing means is characterized in that the structure is symmetrically inclined around the center vertex to be distributed and distributed on the wall of the drilled hole, the tension member accommodated in the protective cap, based on the cross-sectional center of the drilled hole By being symmetrically accommodated and fixed, the symmetrical dispersion of the tensile force is possible.

In particular, the present invention can be applied to both the method of removing the tension member or the non-removable anchor, and take a simple structure but can effectively press the wall of the drilled hole.

Other preferred embodiments of the present invention will be described in detail.

By forming two or more anchor bodies in multiple stages, there is an advantage in that the external force applied to the tension member can be effectively distributed.

In addition, by the pressing means having an inclined gradient surface, it is characterized in that the soft ground reinforcement can be sufficiently exhibited by effectively transmitting the repulsive force against the external tensile force to the wall of the drilled hole.

1 is a perspective view of a multi-stage anchor according to a preferred embodiment of the present invention,
2 is a cross-sectional view of the construction of the anchor of FIG.
3 is an enlarged view of a portion C of FIG. 2;
4 is an exploded perspective view of a portion of FIG. 1;
5 is a perspective view of the multi-stage anchor according to another embodiment of the present invention,
6 is a view for explaining the stress relationship in the pressing means.

Hereinafter, with reference to the drawings, it will be described preferred embodiments of the present invention.

However, the scope of the present invention is not limited only to the specific embodiments, and it is apparent that all equivalent inventions that can be modified at the level of ordinary skill in the art belong to the scope of the present invention.

1 is a perspective view of a multi-stage anchor according to a preferred embodiment of the present invention, the present invention comprises a plurality of anchor body parts a and b and tension members (100, 102, 104, 106) connected between them.

FIG. 2 shows a state constructed as a cross-sectional view observed from the direction A in FIG. 1.

Referring to FIG. 2, some of the two strands 104 and 106 of the plurality of tension members (four strands) are accommodated in and fixed to any one of the plurality of protection caps 400 to stay on the upper anchor body (part a of FIG. 1). do.

As shown in FIG. 1, the remaining tension members 100 and 102 extend to part b of FIG. 1, and the tension member is accommodated and fixed in the same manner as the anchor body part of part a of FIG. 1.

The reason for taking such a multistage anchor structure is as follows.

That is, the conventional anchor has a disadvantage that the concentrated force is applied by concentrating the tensile force applied to the tension member to one anchor body because the anchor body portion is not provided in plurality, but in the present invention, the load can be effectively distributed to ensure sufficient stability. It was made.

As described above, a plurality of strands (four strands in Figure 1) or more through the tension member (100, 102, 104, 106) is introduced through the plurality of receiving holes 205 through the upper, the pressing means formed in the shape of the inclined gradient surface of the head It is located in the uppermost part of the a, b partial anchor body of 1.

The role of the pressing means is to ensure that the anchoring force is secured by transmitting the repulsive force against the tensile force applied to the tension members directly to the wall of the hole (see Fig. 2), the stress on the pressing means in Figure 6 The relationship is shown.

The same pressing means is located in the b-part anchor body, and as shown in FIG. 2, the shape of the pressing means has a solid shape (conical shape). The gradient surface shape of the pressing means may be implemented in a symmetrical form with respect to the center of the drill hole cross section as shown in FIG. (E.g., spikes, protrusions, not shown) has the advantage of not having.

On the other hand, fixing members 300 and 302 which function as spacers are formed at the rear side of each pressing means to fix the intervals of the tension members. The through hole is formed in the fixing member so that the tension member passes therethrough.

Hereinafter, the portion C of FIG. 2, that is, the portion in which the tension member is accommodated and fixed will be described with reference to FIGS. 3 and 4. Figure 4 shows only one of the four strands of tension member for ease of understanding.

One of the tension members, the tension member 104 (indicated in black in FIG. 3), passes through the pressing means 200 and is introduced into the upper side of the protective cap 400.

The fixing wedge 450 is accommodated from the lower side of the protective cap 400, and the fixing wedge presses the tension member outer surface to fix the tension member end.

The lower end of the fixing wedge is provided with a support plate 500 for supporting the fixing wedge and the support plate is coupled to the inside of the protective cap 400 and the screw 505. The support plate is preferably made of a material that is broken when subjected to a constant load in order to remove the tension member in the future.

An elastic means 600 such as a spring is pressed upwards to the lower portion of the support plate 500, and the lower surface blocking portion 404 is coupled to the fixing member 300 through the protrusion 405 (see FIG. 2).

The fixing wedge 450 has an inner diameter corresponding to the end diameter of the tensioning member, and a protrusion is formed at one inner side thereof, thereby minimizing the flow in the tensioning member assembled into the fixing wedge.

The fixing wedge 450 is separated into several (Fig. 4) This is a structure in case the removal of the tension member in the future. That is, when a load in the downward direction is applied from the upper end of the tension member to remove the tension member 104, the support plate 500 is broken and the fixing wedges 450 separated into several pieces are dropped by gravity and elastic means 600 Falls into space occupied by).

3 and 4 are only shown in the case of the removable anchor which removes the tension member after the construction of the anchor. Although not shown, the multi-stage load distribution anchor structure of the present invention can be applied to the non-removable tension member. to be.

On the other hand, the tension members, based on the cross-sectional center of the drilling hole, by symmetrically accommodated, fixed to enable symmetrical dispersion of the tensile force.

That is, as shown in Figure 1, the four strands of the tension member is symmetrically accommodated and anchored in two strands in the first anchor body (part a), the remaining two strands of tension member are symmetrically received in the second anchor body (part b) , Are settled. This structure is such that the tensile force applied to the tension member is evenly distributed in the anchor body.

Figure 5 shows another embodiment of the present invention, which differs only in the shape of the pressing means.

As described above, in addition to the conical shape, the gradient surface of the pressing means 200 may form a flat gradient surface 705 and 706 bilaterally from the upper end as shown in FIG. 5.

That is, by taking a structure in which the center vertex or the vertex line is centered and symmetrically inclined to be distributed and pressurized on the wall of the drilled hole, the pressing means can exert pressure with the symmetry on the wall of the drilled hole 800. It becomes possible.

In FIG. 5, the portions 951 and 952 partitioned in a parabolic shape correspond to the ground resisting zones 951 and 952 in the ground 950, whereby the pressing means 700 and 702 are drilled holes 800 by the tension member upward. The area which exerts pressure on the wall is shown.

The ground resistive zones 951 and 952 may be partitioned in a parabolic form. In the present invention, since the pressing means 700 and 702 are formed in multiple stages, the ground resistive zones are generated in two places as shown in FIG. 5.

As a result, since the load is distributed, the anchor body can be more stably installed, especially when the load concentrated on the anchor body such as the soft ground needs to be avoided.

The stress distribution in the vicinity of the gradient surface of the upper part of the pressing means 200 will be described in more detail with reference to FIG. 6. 6 illustrates a case where the conical pressing means 200 shown in FIG. 1 is applied.

F1 is the force exerted on the tension member, and F2 and F3 are normal stresses caused by F1 and are the repulsive force exerted on the urging means from the grout 900 around the urging means. Of course, the same force as the repulsive force is transmitted from the pressing means to the grout portion, and the force is transmitted to the hole hole wall surface 800.

F4 and F5 are shear stresses applied to the pressing means from the solidifying grout 900.

The forces transmitted to the wall of the drilled hole by the pressure means gradient surface are F2 and F3, which relate to the concept of pressure means having a constant gradient in the present invention.

If the end surface of the pressing means is horizontally flat structure, no force can be transmitted to the wall of the drilling hole, so that a separate means, that is, the protrusion or the spiker structure protrudes from the anchor body and is directly embedded in the wall of the drilling hole It is necessary.

However, in the present invention, by forming a pressing means having a predetermined gradient surface on the upper side, there is an advantage that does not need to attach a separate projection or spiker structure to the anchor body.

On the other hand, the ground resistance zone corresponding to 953 shows a zone (parabolic shape) of the force applied to the wall of the hole 800 from the pressing means, as described with reference to FIG.

The ground resistive zone 953 of FIG. 6 has a different shape from the ground resistive zone 951 of FIG. 5 when viewed in three dimensions, and conical pressurizing means are provided in terms of evenly distributing the force on the wall of the hole 800. 5 may be advantageous than the pressing means of FIG. 5.

Although not shown, the pressing means of the present invention can be formed in a triangular pyramid, square pyramid, other polygonal pyramid shape, of course, the number of the tension member is not limited to four, two or more can be applied.

In addition, it is obvious that the multi-stage anchor body can be expanded to three, four, or the like as well as two (a, b of FIG. 1).

The present invention is a groundbreaking invention that can perform a function as a soft ground reinforcement anchor more securely, since the structure is simple and effectively transmits the force applied to the tension member to the drilling hole and has a multi-stage anchor structure. It can be applied in the field and greatly increase the workability of civil construction.

100, 102, 104, 106: tensile member
205: accommodation hall
300,302: fixed member
400: protective cap 404: lower surface blocking portion 405: protrusion
450: fixing wedge
500: support plate 505: screw
600: elastic means
200,202,700,702: Pressure means
705,706: gradient surface
800: hole
900: grout
950: Ground 951,952,953: Ground resisting zone

Claims (3)

In the load distribution anchor having two or more multi-stage anchor body for soft ground reinforcement,
Pass the two or more tension members 100, 102, 104, 106 through the receiving hole 205, but the shape of the head is formed in the inclined gradient surface, the reaction force against the tensile force applied to the tension member is transmitted directly to the wall of the drilled hole A plurality of pressing means (200, 202) spaced apart at predetermined intervals to improve the fixing force;
Fixing members (300,302) formed on the rear side of each pressing means for fixing the gap of the tension member;
A plurality of protective caps 400 formed between the pressing means and the fixing member to accommodate the tension member from one side and the fixing wedge 450 from the other side to fix the end of the tension member through the fixing wedge;
A fixing wedge 450 having an inner diameter corresponding to an end diameter of the tension member and having protrusions formed therein to press and fix the outer surface of the tension member;
Including,
Some of the plurality of tension members are accommodated and fixed in any one of the plurality of protective caps, the remaining tension member is characterized in that it has a multi-stage anchor body structure by being accommodated in another protective cap,
The gradient surface of the pressing means is a structure that is distributed around the center of the perforated hole to form a symmetrical inclination around the center vertex,
The tension member accommodated in the protective cap,
Multi-stage load distribution anchor, characterized in that the symmetrical dispersion of the tensile force by symmetrically accommodated, fixed on the basis of the cross-sectional center of the drilling hole.

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