KR102244313B1 - Rock fracture guidance system in borehole - Google Patents

Abstract

The present invention relates to a perforated rock crack induction device. The present invention comprises: a double wedge-shaped packer (10); and a perforated rock crack induction device (30) which moves toward an inner peripheral surface of the perforated rock between the double wedge-shaped packers (10) and applies a pressing force to the underground rock. The perforated rock crack induction device (30) is provided with a plurality of pistons (310) movable in a body (300), and causes the piston (310) to generate cracks by tensile displacement in the perforated rock to promote cracking of the perforated rock with an improved splitting pressure.

Description

Rock fracture guidance system in borehole}

The present invention relates to a device for inducing a crack in a perforated rock mass, and more specifically, a plurality of pistons are symmetrically attached around an axial center between a wedge-shaped packer composed of double so that it is operated in two directions, It relates to a perforated rock crack inducing device capable of increasing the split pressure for generating cracks due to tensile displacement in the perforated rock mass by the pressing force of the piston.

In general, in order to crush rock mass for civil works or construction work, a blast hole is formed in the rock mass, and then explosives are put inside the blast hole to explode, or in the case of a special rock mass, it is crushed directly from the outside according to the crystal growth structure of the rock mass. The method has been used.

However, in the case of crushing the bedrock using gunpowder, it has the advantage of being able to crush the bedrock easily.However, the problem of severe noise, vibration and dust due to the use of explosives, and the safety problems associated with the handling of gunpowder, it is difficult to deal with gunpowder. There is a problem that high-level experts are required, and there is a problem that there is always a risk of occurrence of safety accidents during the blasting operation.

In addition, when the rock is crushed by a machine or manpower, there is a problem in that the speed of the rock crushing operation is significantly lower than that of the blasting method, and restrictions according to the actual work environment are severe.

In order to solve the problems of the above blasting method, mechanical excavation method, and manpower excavation method, a vibration-free and noise-free rock crushing method has been proposed in which a hole is formed in the rock mass and then an expandable material is injected to cut the rock mass from the inside.

The vibration-free and noise-free rock crushing method is a method of forming a plurality of perforations of a certain depth in the rock mass, and by injecting water or air into the perforations to apply hydraulic pressure, causing cracks in the walls of the inner perforations to incise the rock mass.

Such a vibration-free and noise-free rock crushing method has the advantage of being able to significantly reduce vibration and noise without being affected by the strength of the rock, since it is possible to cut only necessary parts without indiscriminate cracking of the rock.

However, in the case of the technique of cutting rock by injecting water or air as described above, it is difficult to split the rock when a hole is drilled regardless of the crystal structure of the rock, or if a hole is drilled in a rock with high strength and no crystal structure. There is a problem that the efficiency is very low.

KR 10-1543437 B1 (2015. 08. 10.) KR 10-2049846 B1 (November 28, 2019) KR 10-2123222 B1 (2020. 06. 16.) KR 20-0172715 Y1 (1999. 12. 14.) KR 20-0188756 Y1 (2000. 04. 01.)

It is an object of the present invention to eliminate the blasting method by gunpowder, and to increase the split pressure to generate tensile displacement in the perforated rock mass by the pressing force of the hydraulically operated piston by attaching a plurality of pistons symmetrically to the axial center between packers. It is intended to provide a perforated rock crack induction device that is irrelevant to the crystal structure of the rock mass and can cut only necessary parts without indiscriminate cracking of the rock mass by generating cracks in the rock mass.

Objects and technical problems to be achieved by the present invention are not limited to the above-described technical problems. Therefore, other technical problems not mentioned will be clearly understood by those of ordinary skill in the art from the following description.

A technical feature for achieving the object of the present invention is in the perforated rock crack induction device formed between the double wedge-shaped packers, wherein the perforated rock crack inducing device is movable in the body so that a plurality of pistons are perforated. It includes being able to generate a crack due to tensile displacement with an improved split pressure that moves and presses the inner circumferential surface of the rock mass in this direction.

According to a technical feature of the present invention, the perforated rock crack inducing device includes a cover for restricting movement of the piston in the body.

According to a technical feature of the present invention, the piston includes a piston pressing part in contact with the rock mass; It is integrally formed on one side of the piston pressing portion, and including a piston expansion portion formed to have a cross-section wider than the cross-section of the piston pressing portion, the piston expansion portion in contact with the cover formed in the main body and restricting movement.

According to the technical feature of the present invention, the piston pressing unit is formed in an elliptical shape whose length in the axial direction is longer than the length in the circumferential direction so as to effectively press the perforated rock mass by maximizing the pressing area.

It includes that the length in the axial direction is formed longer than the length in the circumferential direction.

According to the technical feature of the present invention, the piston pressing portion includes a chamfered portion formed at the corner to be able to attenuate the impact stress when hitting the rock.

According to a technical feature of the present invention, the piston expansion portion includes a piston seal formed on an outer circumferential surface.

According to a technical feature of the present invention, the piston is formed in a symmetrical shape on both sides with respect to the axial direction while each is formed on one side, it includes operating in two directions.

The present invention constructed as described above is that the packer is tightly fixed to the perforated rock mass, and a crack is generated by applying a tensile force of increased split pressure to the rock mass by a perforated rock crack inducing device operated by hydraulic pressure. Alternatively, construction efficiency and economy are increased compared to the rock incision method using only the expansion pressure.

In the present invention, the piston driving the wedge-shaped packer applies tensile force to the perforated rock to generate cracks, thereby increasing construction efficiency and economy compared to the conventional rock cutting method using only hydraulic or expansion pressure.

1 is a cross-sectional view in which the perforated rock crack induction device of the present invention is applied to a packer
Figure 2 is a perspective view of the perforated rock crack induction device of the present invention
Figure 3 is an exploded perspective view of the perforated rock crack induction device of the present invention
Figure 4 is a plan view of the perforated rock crack induction device of the present invention
5 is a cross-sectional view before the operation of the perforated rock crack induction device according to the present invention,
(a) is a front sectional view
(b) is a side cross-sectional view
6 is a cross-sectional view after the operation of the perforated rock crack induction device according to the present invention,
(a) is a front sectional view
(b) is an AB cross-sectional view of FIG. 5 (b)

Features and advantages of the present invention may be more clearly understood by the embodiments described by the accompanying drawings.

The application of the present invention is not limited by the configuration and arrangement of components described in the embodiments of the present invention or illustrated in the drawings. The present invention can be implemented in different embodiments, and can be carried out in various ways. In addition, expressions and predicates used in the embodiments with respect to terms such as the orientation of a device or element are used only to simplify the description of the present invention, and do not indicate or imply that the related device or element should simply have a specific orientation. .

In addition, terms or words used in the present specification and claims are not limited to their usual or dictionary meanings and should not be interpreted, and the inventors conform to the technical idea of the present invention in order to explain the terms and concepts of the invention in the best way. It should be interpreted as being written based on the meaning and concept.

Therefore, the present invention is not limited to the examples presented, and is within the equivalent scope of the technical idea of the present invention and the technical idea described in the claims to be described below by a person of ordinary skill in the technical field to which the present invention belongs. Various modifications and changes are possible in.

Although the present invention has been described based on a preferred embodiment with reference to the accompanying drawings, it is apparent to those skilled in the art that various modifications can be made without departing from the technical scope of this description. Accordingly, the scope of the present invention may include many such variations.

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

1 is a cross-sectional view in which the perforated rock crack induction device of the present invention is applied to a packer.

Referring to FIG. 1, a wedge-shaped packer 10 and a perforated rock cracking device 30 are shown.

The wedge-shaped packer (10) is a water injection pipe (110), a hydraulic extension pipe (120), a hydraulic contraction pipe (130), a connecting member (140), a cylinder tube (150), a piston (160), a wedge-shaped cylinder rod (170). ) And a cylinder rod cover 180.

The water injection pipe 110 is located in the center of the double wedge-shaped packer 10 and the perforated rock crack induction device 30.

The hydraulic extension pipe 120 is installed long in the axial direction on the outer periphery of the water injection pipe 110 in a symmetrical position with the perforated rock crack inducing device 30 interposed therebetween to supply hydraulic pressure to the perforated rock crack inducing device 30. It is supposed to be possible.

The hydraulic contraction pipe 130 is installed long in the axial direction on the outer circumference of the hydraulic extension pipe 120 in a symmetrical position with the perforated rock crack inducing device 30 interposed therebetween to operate the perforated rock crack inducing device 30 The hydraulic pressure can be discharged.

The connecting member 140 has a hydraulic injection part 141 formed therein, and the water injection pipe 110, the hydraulic extension pipe 120, and the hydraulic contraction pipe 130 are received and fixed on one side of the wedge-shaped packer 10. It is fixed to and can supply hydraulic pressure to the perforated rock crack induction device 30 and the wedge-shaped packer 10, and a hydraulic discharge part 144 connected to the flow path of the hydraulic contraction pipe 130 is formed to discharge the hydraulic pressure. Can be.

The cylinder tube 150 is fixed to the connecting member 140 at the outer periphery of the hydraulic extension pipe 120 to receive hydraulic pressure.

The piston 160 is movably installed on the outer periphery of the hydraulic extension pipe 120 inside the cylinder tube 150 and can be operated by hydraulic pressure supplied from the hydraulic injection unit 141.

The wedge-shaped cylinder rod 170 has an inclined surface capable of operating the packer 20 and is fixed to the piston at the outer periphery of the hydraulic extension pipe 120 so as to be able to move together with the piston.

The cylinder rod cover 180 guides the movement of the wedge-shaped cylinder rod 170 by supporting a surface on the outer circumference of the wedge-shaped cylinder rod 170 while being fixed to the inner circumferential surface of the cylinder tube 150,

The packer 20 is made of urethane or expandable rubber and is expanded by the wedge-shaped cylinder rod 170 to be in close contact with the inner circumferential surface of the perforated rock mass.

The perforated rock crack induction device 30 is composed of a main body 300 and a pressure-pressing piston 310 and a cover 320.

The body 300 has a water injection pipe 301 connected to the water injection pipe 110 in an axial direction in the center, and an accommodation space in which the piston 310 is movable vertically around the water injection pipe 301 ( 302 is formed, and a cover 320 for preventing separation of the piston 310 is fixed outside the receiving space 302.

The accommodation space 302 is formed in an elliptical shape whose length L2 in the axial direction is longer than the length L1 in the circumferential direction in order to improve the pressure of the piston 310.

Meanwhile, a hydraulic extension pipe 304 and a hydraulic contraction pipe 305 are formed on both sides of the water injection pipe 301, respectively.

The hydraulic extension pipe 304 forms a flow path connected to the hydraulic extension pipe 304 to operate the pressure pressurizing piston 310.

In addition, the hydraulic extension pipe 304 forms a receiving space 302 and a flow path through the hydraulic port 306, and this hydraulic port 306 is applied to the hydraulic space 307 formed in the receiving space 302. It is possible to operate the piston 310 by supplying.

The hydraulic contraction pipe 305 forms a flow path connected to the hydraulic contraction pipe 130 so that hydraulic pressure can be discharged.

The pressure-pressing piston 310 includes a piston pressing part 311 and a piston expansion part 312 integrally.

The piston pressing part 311 is formed in an elliptical shape with a length L2 longer in the axial direction than the length L1 in the circumferential direction so that the perforated rock mass can be effectively pressed with an improved split pressure by maximizing the pressing area. The chamfered portion 313 is formed at the edge contacting the inner circumferential surface, so that the impact stress can be attenuated when the rock is pressed.

The plurality of pistons 310 are formed symmetrically on both sides around the axial direction, and two are formed on the upper part of the drawing, and two are formed at the lower part, so that they operate in different directions, and a tensile force can be applied to the perforated rock mass. .

The piston expansion part 312 is integrally formed on one side of the piston pressing part 311, and is formed to have a wider cross section than the end of the piston pressing part 311, and a piston seal 314 is formed on the outer circumferential surface to provide hydraulic pressure. It becomes possible to prevent the leakage of.

Such a piston 310 is in contact with the cover 320 to which the piston extension 312 is fixed to the main body 30 and its movement is restricted.

The cover 320 is formed in an integral form capable of accommodating two pistons 310.

Look at the operating state of the present invention configured as described above.

First, a plurality of perforations having a size that can be inserted by the perforated rock crack inducing device are formed in the rock at a predetermined depth. Then, a drilled rock crack guide device is inserted into the drilled hole.

Thereafter, hydraulic pressure is supplied through the hydraulic injection unit 141.

The hydraulic pressure supplied to the hydraulic injection unit 141 is supplied to the wedge-shaped packer 10 and the crack inducing device 30.

When hydraulic pressure is supplied to the wedge-shaped packer 10, the piston 160 moves in the axial direction, and the wedge-shaped cylinder rod 150 connected to the piston 160 operates the packer 20. That is, while the inclined surface of the wedge-shaped cylinder rod 150 moving in the axial direction contacts the inclined surface of the packer 20, the packer 20 is pushed away from the center of the axis, so that the packer 20 is placed on the inner circumferential surface of the perforated rock mass. Will come into close contact.

And, the hydraulic pressure supplied to the hydraulic extension pipe 120 is supplied to the hydraulic extension pipe 304 formed in the main body 300 of the perforated rock crack induction device 30.

The hydraulic pressure supplied to the hydraulic extension pipe 304 pushes the piston extension 312 of the piston 310 through the hydraulic action space 307 through the hydraulic port 306, as shown in FIG. 310) is moved in the direction away from the axis center in the receiving space 307, and the piston pressing part 3110 presses the perforated rock mass.

When the piston 310 with improved split pressure in an elliptical shape presses the perforated rock mass, the split pressure with improved tensile force acts on the inner circumferential surface of the drilled rock mass, thereby promoting the occurrence of cracks (C).

The hydraulic pressure obtained by pressing the piston 310 on the perforated rock mass is discharged to the hydraulic discharge unit 144 through the hydraulic contraction pipe 130.

So far, we have looked at the center of the preferred embodiment for the present invention.

The embodiments described in the present specification and the configurations shown in the drawings are related to one of the most preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, and thus various equivalents and modified It should be understood that there may be examples.

Therefore, the present invention is not limited to the examples presented, and is within the equivalent scope of the technical idea of the present invention and the technical idea described in the claims to be described below by a person of ordinary skill in the technical field to which the present invention belongs. There may be embodiments in which various modifications and changes are possible.

10: wedge packer
110: water injection pipe
120: hydraulic extension pipe 130: hydraulic contraction pipe
140: connecting member 141: hydraulic injection
144: hydraulic discharge unit
150: cylinder tube 160: piston
170: wedge-shaped cylinder rod 180: cylinder rod cover
20: packer
30: crack induction device
300: main body 301: water injection pipe
302: accommodation space 304: hydraulic extension pipe
305: hydraulic contraction pipe 306: hydraulic port
307: hydraulic space 310: piston
311: piston pressing portion 312: piston expansion portion
313: face cut 314: piston seal
320: cover
C: crack

Claims (7)

In the perforated rock crack induction device 30 formed between the wedge-shaped packer 10 consisting of a double,
The perforated rock crack induction device 30,
A plurality of pistons 310 in the main body 300 move in this direction and are configured to generate cracks due to tensile displacement with a pressure that presses the inner circumferential surface of the perforated rock mass,
In the perforated rock crack induction device 30,
Includes a cover 320 that is detachably coupled to the outside of the receiving space 302 of the main body 300 to prevent separation of the piston 310 provided in the receiving space 302,
In the piston 310,
A piston pressing part 311 in contact with the rock mass; And
It is integrally formed on one side of the piston pressing part 311, and is formed to have a wider cross-section than the end of the piston pressing part 311 and is in contact with the cover 320, thereby restricting the movement of the piston pressing part 311 Piston extension 312 to be;
Is included,
In the main body 300,
A water injection pipe 301 formed in the longitudinal direction in the center of the main body 300;
A hydraulic extension pipe 304 formed on one side of the water injection pipe 301; And
A hydraulic contraction pipe 305 formed on the other side of the water injection pipe 301;
A perforated rock crack induction device, characterized in that it is included.
delete delete The method according to claim 1,
The piston pressing part 311,
Including that the length in the axial direction (L2) is formed in an elliptical shape that is longer than the length in the circumferential direction (L1) so that the perforated rock mass can be effectively pressed by maximizing the pressing area,
Perforated rock crack induction device.
The method according to claim 1,
The piston pressing part 311,
Including that the chamfered portion 313 is formed at the corner to be able to attenuate the impact stress upon hitting the rock mass,
Perforated rock crack induction device.
The method according to claim 1,
The piston expansion part 312,
Including that the piston seal 314 is formed on the outer circumferential surface,
Perforated rock crack induction device.
The method according to claim 1,
The piston 310,
Including that while two are formed on one side, each is formed in a symmetrical shape on both sides of the axial direction and operates in two directions,
Perforated rock crack induction device.

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