KR101440429B1 - Grouting injection vertical divice - Google Patents

Abstract

The present invention has a screw-shaped mixing unit penetrating the internal flow path of a grouting rod which forms a flow path to discharge a plurality of injected grouting chemical solutions in the shaft direction to swirl the flow of the grouting chemical solutions and mix the solution to effectively derive the function of the grouting chemical solutions. The present invention can also enhance the drying performance and soil bearing capacity. The present invention simultaneously forms a forward swirling section and a backward swirling section by twisting a plate material in the shape of the mixing unit to enhance the kneading degree of the grouting chemical solutions.

Description

{GROUTING INJECTION VERTICAL DIVICE}

The present invention relates to a grouting tip apparatus, and more particularly, to a grouting tip apparatus that forms a screw-shaped mixing unit that axially passes through a grouting rod flow path forming a flow path through which a plurality of grouting chemical fluids are injected and discharged, To a grouting tip apparatus capable of effectively exerting the function of a grouting chemical solution.

Generally, the grouting method is a method in which, in order to reinforce a soft ground or to prevent a settlement of a structure erected on a soft ground, a hole is made in the ground where the cement slurry or the chemical solution as the fluidity filling material is filled, Which is a method of increasing the water-repellency of the water.

The LW (Labiles Wasserglass) method is a method in which a filling material (injection material) having a special property is infiltrated into the ground in order to improve the ground characteristics in accordance with the purpose of use, Sodium silicate) and a small amount of cement are mixed well to wait for the cement to settled, and the above-mentioned water is injected.

In this LW method, there are one shot method and 1.5 shot method depending on the injection method of the filler.

The one-shot method is a method in which a diluted watery liquid is mixed with a small amount of cement, and then a floating matter is injected into the ground after a lapse of a predetermined time.

However, the method of injecting by the one shot method is theoretically reasonable and has a good infiltration effect. However, the cement can not be injected during sedimentation, and the gel time is 30 to 60 minutes, It is difficult to adjust the time, and there is a drawback that the material is wasted by injecting only the water above the cement.

In order to compensate for these drawbacks, the 1.5 shot method is disclosed. In the 1.5 shot method, the cement liquid and the water glass liquid are supplied in the same pressure through separate pumps, respectively, and mixed with the heterogeneous solution in the injection tube connected to the Y tube And the filler is injected into the ground through the through hole formed in the lower part.

As a representative example using the 1.5 shot method, there is a grouting method using a Manchette Tube, which will be briefly described as follows.

1 is a partial cross-sectional view showing a state where a conventional Manut tube applied to a grouting construction is inserted into the ground.

In the conventional 1.5 shot method using a Manh tube, a plurality of injection ports A are formed on the outer circumferential surface, and a rubber sleeve 5 is attached to the injection port A to manufacture the Manhattan tube 2.

Next, the manhattan tube 2 is drawn into a casing inserted into the ground, a sealing material 4 is injected between the manhattan tube 2 and the casing (not shown), and then the casing is pulled out and removed .

Next, the injection tube 1 having the two packers 3a, 3b spaced apart from each other is inserted into the manhattan tube 2, and the pressurized water is injected from the desired position.

At this time, as shown in FIG. 1, a certain space of the manhattan tube 2 is kept sealed by the packers 3a and 3b.

As a result, the pressure of the pressurized water is increased in the sealed space of the manifold tube 2 and the pressure of the space portion is increased. Thus, the pressurized water ejected pushes the rubber sleeve 5 blocking the injection port A, The sealing material 4 formed along the outer circumferential surface of the sealing material 4 is broken to form a passage through which the filling material is ejected in a subsequent step.

Next, the filler is injected into the injection tube 1 inserted into the manhattan tube 2, and the injected filler is injected into the ground through the passage formed in the sealant 4 destroyed in the previous step to form a grouting area .

By repeating this series of processes according to the position in the ground, the grouting construction for the ground is completed.

However, in the above-mentioned prior art, the cement liquid and the water glass liquid are supplied to the injection pipe connected to the Y tube through a separate pump to supply the same to the Y tube, the solution is mixed, and the filler is injected into the ground through the through- There was a problem that the cement liquid and the water glass liquid were injected in a state where they were not mixed well in the injection tube.

Korea Patent No. 10-0671934

It is an object of the present invention to provide a mixing unit having a screw shape penetrating axially through a flow path of a grouting rod for forming a flow path through which a plurality of grouting chemical liquids are injected and discharged to vortex the flow of grouting chemical solution, And to provide a grouting tip apparatus in which the drying performance and the ground supporting force are improved.

Another object of the present invention is to improve the kneading degree of the grouting chemical liquid by simultaneously forming the forward vortex section and the reverse vortex section by twisting the shape of the mixing section.

According to an aspect of the present invention, there is provided a grouting rod for forming a path through which a plurality of grouting fluids are injected and discharged, A mixing unit installed in the groove of the grouting rod in an axial direction to vortex the flow of the grouting chemical solution to mix the flow of the grouting chemical solution and form a forward vortex section and a reverse vortex section simultaneously; And a backflow preventing cap for closing the flow path of the grouting rod to prevent the backflow of the soil into the flow path.

The grouting rod forms a plurality of spray holes through which the grouting chemical liquid is discharged to the discharge tip where the backflow preventing cap is coupled. The grouting rod blocks the backflow of the soil into the flow passage by blocking the spray hole with the discharge stopper do.

Further, the end of the mixing unit is integrally coupled to the backflow preventing cap.

The mixer may further include a forward vortex section and a reverse vortex section formed by twisting a plate material into a screw shape.

In addition, the mixing unit forms a vortex impingement part between the forward vortex section and the reverse vortex section.

The vortex impingement portion may be any one of a forward friction surface disposed in a forward vortex direction, a reverse friction surface disposed in a reverse vortex direction, and a horizontal friction surface disposed in a horizontal direction.

Further, a crushing protrusion for crushing agglomerates of the grouting chemical liquid on the screw vanes of the vortex section and the reverse vortex section to be crushed is formed.

In addition, the crushing protruding portion is finely cut along the outer circumference of the screw blade to form a brush-shaped concavo-convex piece.

The crushing protrusions are characterized by forming irregularities on the surface of the screw blades.

The present invention is characterized in that a screw-shaped mixing portion that axially passes through a grouting rod flow path that forms a flow path through which a plurality of grouting chemical fluids are injected and discharged is formed so that the flow of the grouting chemical solution is vortexed and kneaded to effectively perform the function of the grouting solution And has an effect of improving the drying performance and the ground supporting force.

Further, the present invention has the effect of improving the kneading degree of the grouting chemical liquid by simultaneously forming the forward vortex section and the reverse vortex section by twisting the shape of the mixing section.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a partial cross-sectional view showing a state where a Manhattan tube applied to a grouting construction of the prior art is inserted into the ground. FIG.
2 is a perspective view showing a grouting tip apparatus according to the present invention.
Figs. 3A to 3C are front views showing a mixing unit structure of a grouting tip apparatus according to the present invention; Fig.
4 is a front view showing a structure in which a crushing protrusion is formed on a surface of a mixing part according to the present invention;
5 is a sectional view of a grouting tip apparatus according to the present invention.

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

FIG. 2 is a perspective view showing a grouting tip apparatus according to the present invention, FIGS. 3a to 3c are front views showing a mixing unit structure of a grouting tip apparatus according to the present invention, and FIG. 4 is a cross- Sectional view.

Referring to FIG. 2, the present invention relates to a grouting tip apparatus for strengthening a ground by injecting a grouting chemical liquid consisting of a water glass liquid and cement by being inserted into the ground, and includes a grouting rod 110, a mixing unit 120, And includes a backflow prevention cap (130).

First, a grouting rod 110 for forming a flow path 111 through which a plurality of grouting chemical liquids are injected and discharged is disclosed.

The grouting rod 110 may be made of a cylindrical metal tube and forms a female screw tab at the inlet side and the discharge side end, respectively, where the grouting solution is injected.

The backflow prevention cap 130 is spirally coupled to the discharge side end and a plurality of spray holes 113 through which the grouting chemical solution is discharged may be formed at the discharge end where the backflow prevention cap 130 is coupled.

At this time, a plurality of the spray holes 113 may be radially formed on the outer surface of the grouting rod 110, or may be formed in a multi-layer structure.

The discharge stopper 115 may be made of a rubber material, and the grouting rod 110 may be formed of a material having a high melting point, When the grouting solution is injected into the grouting rod 110 by using a pump, the grouting solution is separated from the spray hole 113 by the pressure of the grouting solution, (113).

Next, a mixing unit 120 installed through the grooves 110 in the axial direction of the grouting rod 110 is disclosed.

The mixing unit 120 is a channel formed by twisting a plate material into a screw shape. The mixing unit 120 mixes the flow of the grouting chemical solution and mixes the flow of the grouting chemical solution so that the forward vortex section 121 and the reverse vortex section 123 are simultaneously formed to improve the kneading ability of the grouting chemical solution.

In this case, for convenience, the side injected in the order of injection of the grouting chemical solution is referred to as a forward vortex section, and the side to be discharged is referred to as a reverse vortex section, and the forward vortex section and the reverse vortex section form twisted screws in opposite directions.

Therefore, at the point where the forward vortex section 121 and the reverse vortex section 123 meet, the vortex flow of the grouting chemical solution is abruptly changed and fluid collision occurs at this time.

Such a fluid collision can act as a force to crush the agglomerated components in the grouting chemical solution.

3A to 3C, the mixing unit 120 may form an optional vortex impingement part 125 between the forward vortex section 121 and the reverse vortex section 123.

The vortex impingement portion 125 may include any one of a forward friction surface 125a disposed in the forward vortex direction, a reverse friction surface 125b disposed in the reverse vortex direction, and a horizontal friction surface 125c disposed in the horizontal direction. . ≪ / RTI >

The vortex impingement portion 125 may be manufactured in various forms without being limited to the shapes shown in FIGS. 3A to 3C. For example, various types of concave and convex portions can be formed on the surface of the vortex impingement portion 125 in order to increase the grinding efficiency.

Next, a backflow prevention cap (130) for closing the end of the flow path (111) of the grouting rod (110) to prevent the backflow of the soil into the flow path (111) is disclosed.

The backflow preventing cap 130 has a cylindrical structure that forms a male screw tab that engages with the female screw tab of the grouting rod 110. At this time, the end of the mixing unit 120 may be integrally coupled to the backflow prevention cap 130.

The present invention is characterized in that a screw-shaped mixing portion that axially passes through a grouting rod flow path that forms a flow path through which a plurality of grouting chemical fluids are injected and discharged is formed so that the flow of the grouting chemical solution is vortexed and kneaded to effectively perform the function of the grouting solution And the drying performance and the ground supporting force are improved.

Further, according to the present invention, the degree of kneading of the grouting chemical liquid can be improved by simultaneously forming the forward vortex section 121 and the reverse vortex section 123 by twisting the shape of the mixing section.

4 is a front view showing a structure for forming a crushing protrusion on the surface of a mixing part according to the present invention. Referring to FIG. 4, a crushing protrusion 127 may be formed on the screw vanes of the forward vortex section 121 and the reverse vortex section 123 to collide agglomerates of the grouting chemical solution to be crushed.

At this time, the crushing protruding part 127 may be finely cut along the outer circumference of the screw blade to form a brush-shaped concave-convex piece 127a, or an irregular needle 127b may be formed on the surface of the screw blade.

The operation of the present invention will be described with reference to FIG. A connector 140 may be coupled to the grouting rod 110 inlet side of the present invention. The connector 140 connects the grouting rod 110 to the grouting liquid supply line.

At this time, since the structure of the grouting chemical liquid supply line is widely known, a description thereof will be omitted here.

A plurality of combinations of grouting fluids are injected into the grouting rod 110 through the connector 140.

At this time, the injected grouting solution penetrates through the mixing part 120 to form a vortex, and the grouting solution having a plurality of combinations is kneaded.

At this time, the mixing unit 120 of the present invention allows the grouting chemical solution that has passed through the forward vortex section 121 to pass through the reverse vortex section 123, thereby doubling the kneading effect.

At this time, the vortex impingement part 125 is formed between the forward vortex section 121 and the reverse vortex section 123, so that the ingot in the grouting chemical solution can be broken.

Thereafter, the discharge stopper 115 is disengaged by the pressure of the grouting solution poured to the tip of the grouting rod 110, thereby opening the spray hole 113 to spray the grouting chemical solution.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You can understand that you can. For example, a person skilled in the art can change the material, size and the like of each constituent element depending on the application field or can combine or substitute the embodiments in a form not clearly disclosed in the embodiments of the present invention, Of the range. Therefore, it should be understood that the above-described embodiments are only illustrative in all aspects and should not be construed as limiting the scope of the invention, and such modified embodiments are included in the technical idea described in the claims of the present invention.

110: Grouting rod
111: Euro
113: Spray hole
115: Discharge plug
120: mixing section
121: Forward vortex section
123: Reverse vortex section
125: vortex portion
125a: forward friction surface
125b: Reverse friction surface
125c: Horizontal friction surface
130: Backflow prevention cap
140: Connector

Claims (9)

A grouting rod 110 forming a flow path 111 through which a plurality of grouting fluids are injected and discharged; The grouting rod 110 is provided with an inner channel 111 extending axially through the grouting rod 110 so that the flow of the grouting chemical solution is vortexed and kneaded to form a forward vortex section 121 and a reverse vortex section 123, (120); And a backflow prevention cap 130 sealing the end of the flow path 111 of the grouting rod 110 to prevent the backflow of the sludge into the flow path 111,
The grouting rod 110 is formed with a plurality of spray holes 113 through which a grouting chemical solution is discharged to the discharge end where the backflow preventing cap 130 is coupled, and the spray hole 113 is closed by the discharge stopper 115, Temporarily shutting off the flow back into the flow path,
The end of the mixing unit 120 is integrally coupled to the backflow prevention cap 130,
The mixing unit 120 forms the forward vortex section 121 and the reverse vortex section 123 in a screw form by twisting the plate material and forms a vortex impingement section 123 between the forward vortex section 121 and the reverse vortex section 123. [ 125,
The forward vortical section 121 and the backward vortical section 123 are formed with crushing protrusions 127 for crushing agglomerates of the grouting chemical solution to be crushed,
Wherein the crushing protrusions (127) are finely cut along the outer circumferences of the screw blades to form brush-like concave-convex pieces (127a).
delete delete delete delete The method according to claim 1,
The vortex impingement portion 125 may be any one of a forward friction surface 125a disposed in the forward vortex direction, a reverse friction surface 125b disposed in the reverse vortex direction, and a horizontal friction surface 125c disposed in the horizontal direction Wherein the grouting tip apparatus comprises:
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