KR102554651B1 - Slope reinforced retaining wall structure using fixing member - Google Patents

Abstract

The present invention relates to a slope-reinforced retaining wall structure using a passive resistor.
Accordingly, the technical point of the present invention is to construct a retaining wall structure for slope reinforcement (covering grass, gravel, stone, concrete, etc. to prevent slopes such as roads, tracks, and waterways from being washed away by water), passive resistors at the ends of reinforcing bars is installed to greatly improve the strong fixed support for panel retaining walls (laminated retaining wall panels) and the resistance when pulling out, which makes the funnel-shaped steel cone and the fixing nut fixing it the anchoring force of the reinforcing bar member in the slope Non-shrinkage mortar or grout filling curing) is greatly strengthened, so that the durability of the retaining wall structure (resistance to earth pressure is greatly improved, and the function of suppressing displacement of retaining wall blocks caused by earth pressure, fullness, and extrusion) is remarkably improved. characterized by
In addition, the passive resistance body of the present invention is fastened and assembled by a one-touch mounting hole when mounted on a reinforcing bar member, which guarantees simple and rapid workability, excellent fastening and fastening reliability, and is characterized by excellent workability.

Description

Slope reinforced retaining wall structure using fixing member}

In the present invention, in constructing a retaining wall structure for slope reinforcement (covering grass, gravel, stones, concrete, etc. to prevent slopes such as roads, tracks, and waterways from being washed away by water), passive resistors are installed at the ends of reinforcing bar members to panel The strong fixed bearing capacity of retaining walls (laminated retaining wall panels) and the resistance during pulling out are greatly improved, which allows the funnel-shaped steel cone and the fixing nut to fix the fixing force of the reinforcing member in the slope (non-shrinkage mortar or Grout filling curing) is greatly strengthened, so that the durability of the retaining wall structure (resistance to earth pressure is greatly improved, and the function of suppressing the displacement of retaining wall blocks due to earth pressure, fullness, and extrusion) is remarkably improved. Characterized in that It relates to a slope-reinforced retaining wall structure using a passive resistor.

In addition, the passive resistance body of the present invention is fastened and assembled by a one-touch mounting hole when mounted on a reinforcing bar member, which guarantees simple and rapid workability, excellent fastening and fastening reliability, and is characterized by excellent workability.

In general, in the construction method of a slope-reinforced retaining wall structure, excavation work is performed on the slope of the embankment or cutting section according to the construction sequence, and then the first shotcrete is performed and then the drilling hole is worked.

Then, after nailing is done by inserting reinforcing bar members or strands into the drilling holes, when the grout is filled in the drilling holes, wire mesh is installed and secondary shotcrete is performed. When curing is completed later, the reinforcing rod members or strands are tensioned and nailed will complete

Thereafter, the tensioned reinforcing bar member or strand nail is fixed to a plurality of standing and laminated retaining walls (panels or blocks) through a fixing means, and then the back filling space between the retaining wall and the slope is filled with rubble (heavy equipment such as a fork crane is used to is poured from above) to complete the retaining wall structure.

However, conventional reinforcing bar members or strands are mounted in a simple straight axis structure, resulting in poor fixing power, and in particular, when pulling out, the pulling resistance is weak, raising concerns about the stability of the retaining wall structure.

1. Republic of Korea Patent Registration No. 10-1056416 (2011.08.05. registration)

In order to solve the above problems, the present invention constructs a retaining wall structure for slope reinforcement (covering grass, gravel, stone, concrete, etc. to prevent slopes such as roads, tracks, and waterways from being washed away by water), Its purpose is to provide a solid fixing support for panel retaining walls (laminated retaining wall panels) and greatly improved resistance when pulled out by mounting a passive resistor on.

The present invention has a funnel-shaped steel cone and a fixing nut fixing it, so that the anchoring force (non-shrinkage mortar or grout filling curing) of the reinforcing bar member in the slope is greatly strengthened, so that the support durability of the retaining wall structure (resistance to earth pressure is greatly improved, , displacement of retaining wall blocks due to earth pressure, a function to suppress the phenomenon of full stomach, and being pushed out) is to be provided so as to be remarkably improved.

In addition, the passive resistor of the present invention is fastened and assembled by a one-touch mounting hole when mounted on a reinforcing bar member, which guarantees simple and rapid workability, secures excellent fastening and binding reliability, and provides excellent workability. there is

In order to achieve this object, the present invention is stacked up and down based on the foundation block to form a series of retaining walls, but a fitting groove 110 is formed at the upper end of the body, and a coupling jaw 120 is formed at the lower end of the body a panel retaining wall 100 having a through hole 130 formed in the center of the surface of the body; When part of the longitudinal axis is brought in through the perforated hole of the slope, it is cured by non-shrinkage mortar, but the other part of the axis diverges out of the slope, passes through the soil filling section, passes through the through hole 130 of the panel retaining wall, and then fastens A reinforcing member 200 that allows the nut to be fixed; The funnel-shaped steel cone 310 and the fixing nut 320 are coupled and fixed to the distal end of the reinforcing bar member 200 inserted into the drilling hole to strengthen the pull-out resistance and secure the slope stability, but the steel cone 310 is The diameter of the inner end 311 is narrow based on the direction inserted into the hole, and the diameter of the outer end 312 toward the inlet of the drilling hole is formed to expand widely (while the non-shrink mortar is filled, the outer reverse pulling force increases). The inner end 311 of the cone 310 and one end of the fixing nut 320 have a passive resistance body 300 to be bound by the one-touch mounting hole 400; made up of

At this time, the one-touch mounting hole 400 allows the insertion ring 410 extending from the inner end 311 of the steel cone to protrude, but a plurality of stoppers 420 at set intervals and steps on the outer circumferential surface of the insertion ring 410 ) and a locking jaw 430, and the stopper 420 is provided with an inclined surface 421 in the form of an uphill slope along one rotation direction, but the inclined surface 421 is a fastening groove formed in the fixing nut 320 ( 440), it is formed to be closely fixed to the hemispherical surface of the hemispherical protrusion 450 formed on the inner circumferential surface of the fastening groove 440, and an arc-shaped or hemispherical mounting groove 422 on the high-top height side of the section of the inclined surface 421 This is formed so that the hemispherical surface of the hemispherical projection 450 is coupled in a one-touch fitting method while preventing over-rotation in the circumferential direction while corresponding.

In addition, it is preferable that a plurality of reinforcing resistors 500 are further mounted on a longitudinal line of the reinforcing bar member 200.

In this way, the present invention constructs a retaining wall structure for slope reinforcement (covering grass, gravel, stones, concrete, etc. to prevent slopes such as roads, tracks, and waterways from being washed away by water), passive resistors at the ends of reinforcing bars It has the effect of greatly improving the resistance when pulling out and the solid fixed bearing capacity for panel retaining walls (laminated retaining wall panels) by mounting.

The present invention has a funnel-shaped steel cone and a fixing nut fixing it, so that the anchoring force (non-shrinkage mortar or grout filling curing) of the reinforcing bar member in the slope is greatly strengthened, so that the support durability of the retaining wall structure (resistance to earth pressure is greatly improved, , the occurrence of displacement of retaining wall blocks due to earth pressure, the function of suppressing the phenomenon of full stomach and being pushed out) has the effect of remarkably improving.

In addition, the passive resistor of the present invention is fastened and assembled by a one-touch fitting when mounted on a reinforcing bar member, which guarantees simple and rapid workability, excellent fastening and fastening reliability, and has excellent workability.

1 is an exemplary side view showing a slope-reinforced retaining wall structure using a passive resistor according to the present invention;
2 is an exemplary view showing a passive resistor according to the present invention;
3 to 6 are exemplary views showing one-touch fittings according to the present invention;
7 to 8 are exemplary views showing a reinforcing resistor as an additional embodiment of the present invention.

The following describes the present invention with reference to the accompanying drawings.

First, as shown in FIG. 1, the present invention is largely composed of a panel retaining wall 100, a reinforcing bar member 200, and a passive resistor 300.

Accordingly, the panel retaining wall 100 is stacked up and down based on the foundation block to form a series of retaining walls, but a fitting groove 110 is formed at the upper end of the body and a coupling jaw 120 is formed at the lower end of the body. It is formed, and a through hole 130 is provided at the center of the surface of the body.

Accordingly, the reinforcing bar member 200 is cured by non-shrinkage mortar when a part of the longitudinal axis is brought in through the perforation hole of the slope, but the other part of the axis is branched out of the slope and passed through the soil filling section through the through hole of the panel retaining wall After passing through (130), it is formed so that the fastening nut is fixed.

Accordingly, as shown in FIG. 2, in the passive resistor 300, the funnel-shaped steel cone 310 and the fixing nut 320 are coupled and fixed to the distal end of the reinforcing bar member 200 inserted into the drilled hole to strengthen the pull-out resistance. It is formed to secure slope stability while doing so.

At this time, the diameter of the inner end 311 of the steel cone 310 is narrow based on the direction in which it is inserted into the drilling hole, and the diameter of the outer end 312 toward the inlet of the drilling hole is widened (the outer end 312 is filled with non-shrink mortar). reverse pulling force is increased), and the inner end 311 of the steel cone 310 and one end of the fixing nut 320 are formed to be bound by the one-touch mounting hole 400.

Therefore, as shown in FIGS. 3 to 6, the one-touch mounting hole 400 allows the insertion ring 410 extending from the inner end 311 of the steel cone to protrude, but the outer circumferential surface of the insertion ring 410 It is formed to be provided with a plurality of stoppers 420 and locking jaws 430 at set intervals and steps.

At this time, the stopper 420 is provided with an inclined surface 421 of an uphill shape along one rotation direction, but when the inclined surface 421 is inserted into the fastening groove 440 formed in the fixing nut 320, the fastening groove 440 It is formed to be fixed in close contact with the hemispherical surface of the hemispherical projection 450 formed on the inner circumferential surface.

In addition, an arc-shaped or hemispherical mounting groove 422 is formed on the high-top height side of the section of the inclined surface 421 so that the hemispherical surface of the hemispherical projection 450 corresponds to prevent over-rotation in the circumferential direction and is coupled in a one-touch fitting method is formed

Accordingly, an arc-shaped or hemispherical mounting groove 422 is formed on the high-top height side of the section of the inclined surface 421 so that the hemispherical surface of the hemispherical protrusion 450 corresponds to prevent over-rotation in the circumferential direction and is coupled in a one-touch fitting method It is formed (pressing and fastening after being stored at the top height).

In addition, the locking jaw 430 protrudes while being disposed in a direction orthogonal to the stopper 420 (90 °) or at an angle spaced apart from a set angle, but the locking jaw 430 has a cross section in the shape of a digger with an opening in one direction. It is formed to have a long horizontal surface (the long side connecting the short leg of the shape of the letter) is inserted into the fastening groove 440 while entering the bottom (or side end) of the hemispherical projection 450 with the rotation of the insertion ring 410. 410 is formed so that it does not fall outward.

In other words, the one-touch fitting 400 of the present invention is fitted and assembled while the insertion ring corresponds to the fastening groove, and the insert ring has a stopper and a locking jaw formed on the outer circumferential surface to correspond to the hemispherical projection of the fastening groove, thereby rotating the stopper when fastening. Through the inclined surface and the mounting groove, the hemispherical surface of the hemispherical projection is formed to be pressed and fastened in the form of male and female irregularities.

At this time, the locking jaw is formed so that the long horizontal surface of the locking jaw is caught on the inner end of the hemispherical protrusion in a state where the insertion ring is assembled in the fastening groove and does not fall out.

This is to ensure rapid coupling, fastening, easy workability and high fastening reliability.

Accordingly, as shown in FIGS. 7 to 8 , it is preferable that a plurality of reinforcing resistors 500 are further mounted on the longitudinal line of the reinforcing bar member 200 .

At this time, the reinforcing resistor 500 is a disk body, so that a slit-shaped incision 510 is formed on one side, but the incision groove 510 (also providing a path for non-shrinkage mortar to flow) is a reinforcing bar member 200 When the incision groove 510 is caught and fixed for each protruding joint band 210 of the reinforcing bar member while being inserted in a direction orthogonal to the axis of, the non-shrinkable mortar is filled in the drilling hole, and then, when curing is completed, resistance due to drawing is reinforced formed so that

Accordingly, an accommodation groove 520 is formed on the inner periphery of the incision groove 510 of the reinforcing resistor 500 so that the '∪'-shaped elastic pin 530 is inserted inside, but the outer pressing end 531 of the elastic pin 530 On the basis of the silver inner support end (532: elastic force is generated while leaning on the inner wall of the storage groove), elastic force that always tends to spread outward is generated, so that the reinforcing resistor is inserted into the incision groove 510 for the reinforcing bar member 200 having a circular cross section. It is formed so that it is firmly fixed without flow while being tightly fitted when fitted through.

In addition, a clamp-shaped protrusion 534 is formed at the outer corner of the extension end 533 connecting the inner pressure end 532 and the outer pressure end 531 so that it is in close contact or compressed while corresponding to the arc surface of the reinforcing bar member. It is formed (formed so that the elastic pin and the reinforcing bar member do not separate or come off from each other by ensuring the adhesiveness and compression).

At this time, a wedge 535 is formed on the outer end of the outer pressing end of the elastic pin 530, and the protruding rib 220 of the reinforcing bar member is located in the radial portion based on the circular cross section of the reinforcing bar member and is horizontal along the longitudinal direction of the reinforcing bar member. The reinforcing resistor 500 inserted through the incision groove 510 while caught on one protruding line or protruding band is formed so that it is fixed in an upward direction (or in a reverse direction to the inserted direction) without being separated or removed.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes are within the scope of the claims.

100 ... panel retaining wall 110 ... fitting groove
120 ... coupling jaw 130 ... through hole
200 ... reinforcing bar member 210 ... protruding joint band
220 ... protruding rib
300 ... passive resistor 310 ... steel cone
311 ... inner end 312 ... outer end
320 ... fixing nut
400 ... one-touch mounting hole 410 ... insertion ring
420 ... stopper 421 ... slope
422 ... Mounting groove 430 ... Catch jaw
431 ... Long horizontal plane 440 ... Fastening groove
450 ... hemispheres
500 ... reinforced resistor 510 ... cut groove
520 ... storage groove 530 ... elastic pin
531 ... outer pressure end 532 ... inner pressure end
533 ... extended end 534 ... protrusion
535 ... wedge

Claims (3)

It is stacked up and down based on the foundation block to form a series of retaining walls, but a fitting groove 110 is formed at the upper end of the body, a coupling jaw 120 is formed at the lower end of the body, and through the center of the face of the body a panel retaining wall 100 to form a ball 130; When part of the longitudinal axis is brought in through the perforated hole of the slope, it is cured by non-shrinkage mortar, but the other part of the axis diverges out of the slope, passes through the soil filling section, passes through the through hole 130 of the panel retaining wall, and then fastens A reinforcing bar member 200 that allows the nut to be fixed; The funnel-shaped steel cone 310 and the fixing nut 320 are coupled and fixed to the distal end of the reinforcing bar member 200 inserted into the drilling hole to strengthen the pull-out resistance and secure the slope stability, but the steel cone 310 is Based on the direction inserted into the inner end 311, the diameter is narrow, the diameter of the outer end 312 toward the inlet of the drilling hole is formed to expand widely, and the inner end 311 of the steel cone 310 and the fixing nut ( 320) has a passive resistance body 300 to be bound by the one-touch mounting hole 400 at one end; In the slope-reinforced retaining wall structure using a passive resistor composed of,
The one-touch mounting hole 400 allows the insertion ring 410 extending from the inner end 311 of the steel cone to protrude, but the outer circumferential surface of the insertion ring 410 has a plurality of stoppers 420 and It is formed to be provided with a locking jaw 430, and the stopper 420 is provided with an inclined surface 421 in the form of an uphill along one rotation direction, but the inclined surface 421 is a fastening groove 440 formed in the fixing nut 320 When inserted into the fastening groove 440, it is formed to be closely fixed to the hemispherical surface of the hemispherical projection 450 formed on the inner circumferential surface, and an arcuate or hemispherical mounting groove 422 is formed on the high top height side of the section of the inclined surface 421. A slope-reinforced retaining wall structure using a passive resistor, characterized in that the hemispherical surface of the hemispherical projection 450 corresponds and prevents over-rotation in the circumferential direction and is coupled in a one-touch fitting method. The slope-reinforced retaining wall structure using passive resistors according to claim 1, wherein the reinforcing bar member (200) is further equipped with a plurality of reinforcing resistors (500) on a longitudinal line. delete

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