KR100972357B1 - Expandable tube type rock bolt - Google Patents

Abstract

PURPOSE: An expandable tubular lock bolt which can be for rock reinforcing work is provided to prevent the corrosion of the lock bolt by residual pressure fluid. CONSTITUTION: An expandable tubular lock bolt comprises an extensive part(100), an injection part(120) and a sealing part(140). An inner space and a folding block are formed on the extensive part. Pressure fluid is introduced to the inner space. The folding block is formed on one part of exterior and folded toward outside. The injection part is combined in one end of extensive part in order to be connected with the inner space of extensive part. Pressure fluid is supplied to the injection part from a pressure fluid feeder. The sealing part seals the end of the extensive part toward the injection part.

Description

Expandable tube type rock bolt

The present invention relates to a lock bolt used for rock reinforcement, and more particularly, to inject a high-pressure pressure fluid into the lock bolt quickly and easily during construction of the rock bolt to shorten the expansion and installation time of the lock bolt. And an expandable tubular lock bolt capable of preventing the corrosion of the lock bolt due to the residual pressure fluid by completely draining the pressure fluid remaining inside the lock bolt to the outside when the construction of the lock bolt is completed. .

In general, in excavating a tunnel, after drilling a foundation tunnel at a constant height and width, in order to prevent the collapse of the foundation tunnel, a number of foundation bolts (lock bolts) are put on the inner side of the foundation tunnel to form a mesh shape. The mesh body is installed and the rock reinforcement work is finally performed on the concrete.

The rock bolt method is generally adopted for rock reinforcement in the rock reinforcement work. The lock bolt method is a method that prevents rock reinforcement and falling rocks by drilling a hole in the wall, inserting a lock bolt in the wall, and then tightening the nut firmly to fix the rock weakened due to blasting during excavation to a solid and stable rock.

The lock bolt method has the advantage of supporting the base using the strength of the base itself, and can be used for a wider range of lipids. In addition, it is widely adopted in tunneling or tunnel excavation due to the advantage of increasing economic efficiency and having high adaptability to changes in the cross-sectional shape of the tunnel.

On the other hand, there is an expandable lock bolt as a reinforcing lock bolt used in conventional tunnel or tunnel excavation. The expandable lock bolt was to expand the steel tube by supplying a high pressure water inside the hollow steel tube to expand the steel tube so that the lock bolt can be firmly adhered to the inner wall of the rock.

As shown in FIG. 1, the expandable lock bolt communicates with a tube-shaped steel tube 6 having a form in which one side of the outer circumferential surface is infiltrated therein, and one end of the steel tube 6 and the high-pressure water It consists of the injection part 5 injected and the sealing part 9 which seals the other end of the said steel pipe 6.

The expandable lock bolt having the above-described structure forms a drilled hole 19 at a predetermined depth in the rock 16 to be constructed, inserts the lock bolt 6 into the drilled hole 19, and then locks the lock bolt ( The high pressure water is supplied into the lock bolt 6 through the injection hole 4 formed on the side of the injection part 5 of the 6 and expands the lock bolt 6 to the inner wall surface 14 of the rock 16. It is set to be firmly adhered to.

Here, FIG. 1A is a cross-sectional view taken along a line A-A which is a state before the expansion of the lock bolt, and (b) is a cross-sectional view taken along a line B-B which is a state after the expansion of the lock bolt. Reference numeral 6 denotes a cross section of the lock bolt before expansion, and 20 denotes a cross section of the lock bolt after expansion.

FIG. 2 sequentially shows a coupling method between the injection part 5 and the steel tube 6 into which high pressure water is injected in the conventional expandable lock bolt. As shown in FIG. 2, the conventional expandable lock bolt inserts an end of a steel tube 6 having a concave portion 7 on one side into the injection portion 5, as shown in (a), and the steel tube. When (6) is fully inserted to the end of the inlet (5) to make the indentation (7) of the end of the steel tube (6) in the C-shape as in (b), then the outer peripheral surface of the steel tube (6) Weld the circular rim of the injection section 5 in contact with the inner circumferential surface of the injection section 5 in the direction of the arrow (c), and drill the injection hole 4 on the side of the injection section 5 to connect to the inner space of the steel tube 6. do. In this case, as shown in (d), the end of the steel tube 6 is completely joined to the inner circumferential surface of the injection portion 5 by welding while being completely sealed by welding. Accordingly, the end of the injection portion 5 to which the steel tube 6 is coupled is maintained in a completely closed state in which water cannot enter or exit. Then, the high-pressure water is supplied into the steel tube 6 through the injection hole 4 formed in the injection part 5 side as shown in (e) to expand the steel tube 6.

Conventional expandable lock bolt having the coupling structure as described above is the end of the steel tube (6) coupled to the injection portion (5) is sealed through welding to form a closed structure in which water can not enter, while high pressure water is The injection hole 4 to be injected has a structure formed on the side of the injection portion 5 in a very small size of about 1 mm on the side of the injection portion 5. Therefore, after the high-pressure water injected in the direction perpendicular to the longitudinal direction of the steel tube 6 through the injection hole 4 is reflected and refracted in the inner space of the end of the steel tube 6, the longitudinal direction of the steel tube 6 is changed. It was introduced to expand the steel tube 6. As described above, the conventional lock bolt is formed at the side of the injection portion 5 in which the injection hole 4 into which the high pressure water is injected is injected and the direction in which the high pressure water is initially injected through the injection hole 4. Since the direction in which water is transported into the steel tube 6 is formed perpendicular to each other, the introduction of water into the steel tube 6 cannot be made quickly in a short time. Accordingly, the expansion of the lock bolt is delayed and the lock bolt is delayed. There was a problem that requires a lot of installation time.

In addition, when the conventional lock bolt is installed on a wall surface such as a tunnel, as shown in FIG. 3, the lock bolt has various inclination angles and is upwardly installed on the tunnel wall, where the lock bolt has been introduced into the lock bolt for expansion of the lock bolt. Even after the installation of the lock bolt, the water was not properly discharged to the outside through the small size of the injection hole (4) formed on the side of the injection portion (5). That is, as shown in FIG. 3, the lock bolt is corroded by water that is not naturally discharged to the outside through the injection hole 4 according to the installation position of the lock bolt, and thus, the fixing force of the lock bolt is increased. There were weaknesses that weakened and caused serious problems in safety.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to partition the internal space of the expansion portion of the expansion portion of the lock bolt into two spaces of semi-circular shape, while the lock bolt is injected pressure fluid The injection part of the lock bolt is formed in a pipe shape, and the pipe injection part is used as an injection hole into which the pressure fluid is injected, thereby quickly and easily injecting a high pressure pressure fluid into the expansion part during the construction of the lock bolt. It is to provide an expandable tubular lock bolt that can shorten the installation time and improve the workability.

In addition, another object of the present invention to completely discharge the water stored inside the lock bolt after the construction of the lock bolt, thereby preventing corrosion of the lock bolt by the residue inside the lock bolt and to increase the stability and construction quality An expandable tubular lock bolt is provided.

In addition, another object of the present invention is to configure a plurality of extensions to be connected to each other, can be used to freely adjust the overall length of the lock bolt to the desired length, if necessary, the rock reinforcement without being limited to the construction depth of the lock bolt It is to provide an expandable tubular lock bolt that can be easily performed.

Expandable tubular lock bolt according to the present invention for solving the above technical problem is formed, the inner space in which the pressure fluid can be introduced, the tube-type expansion with a folding portion formed by folding a portion of the outer surface inward direction part; An injection unit coupled to one end of the expansion unit to communicate with an internal space of the expansion unit, into which pressure fluid supplied from a pressure fluid supply device is injected; And a sealing part for sealing the other end of the expansion part facing the injection part, and the folding part is formed by being folded in a shape of a "(1)" shape to convert the internal space of the extension part into two spaces of a semicircle shape. Compartment, the injection portion is formed in the form of a pipe (pipe) open at both ends, the open end of the injection portion is connected to the expansion portion, the pressure fluid is injected through the other open end of the injection portion It is characterized in that it is configured to be injected in the axial direction of the negative portion to be introduced into the inner space of the extension.

Here, when connecting the injection portion and the expansion portion, by welding the circular edge portion and the straight folding portion portion where the expansion portion and the injection portion meets in the state that the end of the expansion portion is inserted into the open end of the injection pressure, Two semicircular pressure fluid introduction spaces may be formed at the inlet portion of the expansion portion through which the fluid is introduced.

The present invention may further include a pressure plate inserted in the expansion part and supported at one end of the injection part, and the pressure plate may form a mortar injection hole for injecting mortar.

In this case, a screw thread may be formed on an outer surface of the injection unit.

In addition, a plurality of protrusions may be formed on an outer surface of the extension part.

The protrusions may be irregularly arranged on the outer surface of the extension part.

Alternatively, the protrusion may be formed to protrude in a spiral shape along the longitudinal direction on the outer surface of the extension.

The seal has a cone or bullet shape and may be integrally coupled to the end of the extension.

Alternatively, the seal may have a cone or bullet shape and may be detachably coupled to the end of the extension by screwing.

On the other hand, the expansion unit is provided with two or more connected to each other in a line through one or more connection members, the connection member is coupled to the end of each of the expansion portion to be connected to the connector and the male thread formed on the outer surface; The male screw portion and the corresponding female screw portion of the connector may be formed at both ends, respectively, and constitute a sleeve coupled to the connector in a screwed manner.

In addition, the present invention may further include a vibration sensor mounted on the sealing portion.

In this case, the vibration sensor is located in a spaced apart from the lock bolt construction target portion, the electrical means and the output means for expressing the safety abnormality for the rock bolt construction rock by calculating the electrical signal applied from the vibration detection sensor Can be connected.

According to the present invention having the above-described configuration, the injection hole of the lock bolt into which the pressure fluid is injected is formed in a completely open structure at the end of the injection part, so that the injection flow path of the pressure fluid leading from the injection hole at the end of the injection part to the internal space of the expansion part is parallel. Because it is formed and formed, it is possible to quickly and easily introduce the pressure fluid into the internal space of the expansion portion when the injection of the pressure fluid through the injection portion can be expanded quickly. Accordingly, there is an advantage that can shorten the installation time of the lock bolt and improve the workability according to the installation.

In addition, when the lock bolt is installed upwardly perforated on the rock, the residual pressure fluid inside the lock bolt is naturally drained to the outside through an injection hole opened parallel to the end of the injection part, so that the remaining pressure fluid inside the lock bolt is 100% completely. It can be naturally drained, and thus, it is possible to prevent corrosion phenomenon of the lock bolt generated by residual pressure fluid, and to prevent the problem of deterioration of fixation force due to corrosion of the lock bolt.

In addition, the lock bolt of the present invention has a structure in which the folding part inside the extension part is formed in the form of a straight line ("1") to greatly expand the internal space of the extension part. There is an advantage to increase the space utilization inside the expansion portion, such as to easily insert and insert the wiring.

In addition, the lock bolt of the present invention uses an injection end of a pipe type as an injection hole for the pressure fluid, so that an injection hole diameter almost the same as the inner diameter of the injection part or the expansion part can be secured. The pressure fluid can be easily injected into the expansion part, and the residue inside the lock bolt can be easily discharged to the outside when the construction of the lock bolt is completed.

In addition, the lock bolt of the present invention uses a pipe-shaped injection end as a pressure fluid injection hole, so that a separate small injection hole for injection of the pressure fluid into the side of the injection portion of the lock bolt can be processed like a conventional lock bolt. There is an advantage that does not need to.

In addition, the lock bolt of the present invention is not only a few ten times larger than the conventional injection hole is formed in parallel in the axial direction of the expansion portion is excellent accessibility to the inside of the expansion portion has the advantage of easy insertion of safety equipment such as sensors have.

In addition, the present invention in connecting the injection portion and the expansion portion of the lock bolt, in the state in which the end of the expansion portion is inserted into the open end of the injection portion welded and coupled to join the circular edge portion that meets the expansion portion and the expansion By welding and sealing the portion of the straight folding portion at the end portion, two pressure fluid injection spaces having a semicircular shape are formed at the inlet portion of the expansion portion where the pressure fluid is initially introduced, so that the pressure fluid injected from the injection hole of the injection portion is deflected. Since it directly flows in parallel to the semicircular injection space of the extension, the construction time of the lock bolt is shortened due to the rapid expansion of the extension.

In addition, the present invention by forming a mortar injection hole for the injection of mortar in the pressure plate portion supported at the end of the injection portion of the lock bolt, to inject mortar between the drill hole formed in the rock and the lock bolt inserted into the drill hole Since the mortar injection hose does not need to be installed separately, the structure of the lock bolt device is simplified and the manufacturing cost can be reduced by installing additional accessories.

In addition, the present invention forms a screw thread on the outer peripheral surface of the injection portion of the lock bolt, the pressure fluid supply device can be easily coupled or separated on the outer peripheral surface of the injection portion by screwing method, the pressure in the supply process of the pressure fluid through the injection portion Due to the repulsive force according to the supply pressure of the fluid, it is possible to prevent the pressure fluid supply device from being separated from the injection part in advance, thereby eliminating the fear of a safety accident.

In addition, because the lock bolt of the present invention is a regular or irregular protrusions formed on the surface of the extension, the lock bolt is caught or crushed on the rock edge of the fine pattern inside the drilling hole during expansion of the expansion portion immediately after construction Since strong resistance is generated to resist sliding from the drilling hole, there is an advantage that the lock bolt can be more firmly fixed in the drilling hole and can exhibit more stable tensile force.

At this time, if the shape of the protrusion formed on the surface of the expansion portion is formed in a continuous spiral, even if a bolt is pushed out of the hole during the expansion of the bolt during construction of the lock bolt, turn the bolt to turn the screw Since the bolts pushed out of the drill hole due to the slip can be adjusted to the inside of the drill hole by the slip, it is possible to compensate for the slip generated during the bolt expansion process.

In addition, the lock bolt of the present invention by installing a vibration sensor in the expansion portion or the sealing portion, and by connecting the electrical wiring extended from the vibration sensor to the output means for expressing the presence of safety abnormality, tunnel or shaft excavation In the process of blasting can detect the signs of collapse in advance, there is an effect that can prevent the accident.

In addition, the lock bolt of the present invention is provided with two or more expansions when necessary to be connected to each other through a connecting member, so that the length of the lock bolt can be freely extended to the desired length if necessary, lock There is an advantage that the rock reinforcement can be easily performed without being limited by the construction depth of the bolt.

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

The expandable tubular lock bolt according to the present invention is to prevent rock reinforcement and rockfall by fixing rock that is weak due to blasting during tunneling or tunnel excavation to a solid and stable rock, and is generally drilled in the construction target surface. It has a rod shape that can be inserted into the hole, and when it is inserted into the hole, supplying pressure fluid, that is, high pressure water, the bolt expands without any additional work such as grouting, so that it can be firmly fixed to the wall inside the hole. have.

4 is a perspective view showing an expandable tubular lock bolt according to an embodiment of the present invention, Figure 5 is an exploded perspective view of FIG. 6 and 7 are cross-sectional views illustrating cross-sectional structures of sections A-A and B-B of FIG. 4, respectively.

4 to 7, the expandable tubular lock bolt 1 according to the present invention includes an inner space 103 into which a pressure fluid can be introduced, and a folding portion formed by folding a portion of the outer surface inward. The expansion unit 100 is provided with 110, coupled to one end of the expansion unit 100 so as to communicate with the internal space 103 of the expansion unit 100 is supplied from a pressure fluid supply device (not shown) It is configured to include an injection portion 120 is injected into the pressure fluid to be injected, and a sealing portion 140 for sealing the other end of the expansion portion 100 facing the injection portion 120.

The expansion part 100 has a tube shape and an inner space 103 into which a pressure fluid can be introduced, and a folding part 110 formed by folding an outer circumferential surface side of the expansion part 100 inward. Is formed.

As shown in the cross-sectional view of FIG. 7, the folding unit 110 has a cross-sectional structure folded in a straight line (“1”) shape, and the folding unit 110 has left and right sides of the internal space 103 of the expansion unit 100. It is divided into two semicircular spaces.

The expansion part 100 is formed by bending a flat plate to form a tube or pipe, and then press one side of the outer circumference inward along the longitudinal direction to be folded into a straight line ("1") shape. It is manufactured by folding or rolling process.

As described above, the lock bolt of the present invention has an extension portion 100 rather than the lock bolt having a conventional C-shaped folding portion because the folding portion 110 in the expansion portion 100 is formed in a straight ("1") shape. Because of the large internal space), it is possible to easily inject a pressure fluid, as well as to easily insert a vibration sensor, various electrical wiring, etc., it is possible to increase the space utilization inside the expansion unit (100).

On the other hand, in the case of a general lock bolt, it is difficult to generate a stable tensile force by sliding from the hole (slip occurrence) out of the designated position by the movement of the strong but limited lock bolt in the hole after construction, especially the surface of the extension part In this flat case, it is impossible to secure sufficient frictional force with the drilled hole having an inner surface having an irregular surface morphology as the extension is expanded, and thus cannot obtain sufficient fixing force required.

In order to overcome this disadvantage, the lock bolt of the present invention forms a plurality of protrusions 102 in a regular or irregular pattern on the surface of the extension part 100, and the protrusion 102 in the process of expanding the extension part 100. ) Are caught or crushed at the rock edge of the fine pattern inside the drill hole, so that the lock bolt 1 generates a strong resistance against slipping from the drill hole immediately after construction, and the lock bolt 1 is drilled into the drill hole. It is firmly settled in, so that it can exhibit more stable tensile force.

At this time, as an example of regular or irregular formation of the protrusions 102 on the surface of the expansion part 100, the hemispherical protrusion 102 is embossed on the surface of the expansion part 100 as shown in FIG. It may be formed to protrude in the form.

In addition, the shape of the protrusion 102 may be formed in a continuous spiral shape along the longitudinal direction of the extension part 100. The spiral protrusion 102 is formed by turning the bolt and tightening the screw even if the lock bolt is pushed out of the hole in the expansion process of the lock bolt during construction of the lock bolt 1. In addition, the sliding of the bolt pushed out of the drilling hole due to the slip can be adjusted to the inside of the drilling hole to some extent to compensate for the slip generated during the expansion of the lock bolt.

The injection part 120 is a portion in which the pressure fluid supply equipment is bitten so as to inject a pressure fluid, for example, high pressure water, into the internal space 103 of the expansion part 100 to expand the expansion part 100. In the state where the bolt is installed on the rock wall, the expansion part 100 is positioned in the perforation hole and the injection part 120 is exposed to the outside of the rock wall surface.

Here, a bearing plate 160 is supported on the rear side of the injection part 120 during the construction of the lock bolt, and the force (tensile force) introduced into the lock bolt during the construction of the lock bolt 1 is the acupressure plate 160. It is transmitted to the base plate through and acts a compressive force on the base plate between the fixing unit and the pressure plate 160 to reinforce the ground and prevent rockfall.

The injection part 120 has a form in which a pipe is open at both ends. One end of the expansion part 100 is fitted into one open end of the injection part 120, and the other end of the injection part 120 is used as an injection hole 221 into which a pressure fluid is injected. do.

As described above, the lock bolt of the present invention has a structure in which both ends are completely open by the injection unit 120 having a pipe shape, unlike the existing lock bolt structure. It has one structural feature in that it is used.

In this case, the injection hole 221 formed at the end of the injection unit 120 of the present invention has a large diameter of about 5 cm, which is approximately equal to the inner diameter of the injection unit 120 or the expansion unit 100. It is several tens of times larger in diameter than the injection hole of about 1 mm formed on the side of the injection portion of the existing lock bolt. Accordingly, when the pressure fluid is injected into the lock bolt, the high pressure pressure fluid may be rapidly introduced in parallel with the longitudinal direction of the injection part 120 to expand the lock bolt in a short time.

As described above, the lock bolt of the present invention uses one end of the injection portion 120 having a pipe shape as the injection hole 221 through which the pressure fluid is injected, and through the injection hole 221 when the lock bolt is constructed. The pressure fluid can be introduced quickly and easily into the expansion part 100.

In addition, when the lock bolt of the present invention is installed inclined upwardly on the upper portion of the foundation tunnel rock as shown in the construction example of FIG. Since it is naturally drained to the outside through the injection hole 221 formed in a large diameter, water does not remain in the lock bolt, and the entire amount may be completely drained out of the lock bolt. Accordingly, it is possible to prevent corrosion of the lock bolt, which is generated by the water introduced to expand the expansion part 100 of the lock bolt remaining inside the lock bolt.

On the other hand, the injection portion 120 has a structure, is formed at the end of the body 220 so as to support the cylindrical injection portion body 220 and the pressure plate 160 fitted around the expansion portion 100 Consisting of a flange portion 226.

At this time, the thread 222 is formed on the outer peripheral surface of the end portion of the body 220 which is located opposite to the flange portion 226 at a predetermined interval.

Here, the screw thread 222 formed in the body 220 of the injection portion is to ensure easy assembly with the additional device when the lock bolt 1 is inserted into the drilling hole using a separate additional device, By allowing the injection fluid 120 to stably bite the pressure fluid supply device 30 in a screw-tight manner, the pressure fluid supply device is separated by the repelling force of the pressure fluid during the supply of the pressure fluid. Prevent accidents that may occur.

In addition, when the expansion unit 100 is expanded to fix the lock bolt of the present invention in the drilling hole, the pressure fluid supply equipment is separated from the lock bolt, and then the fixing force of the lock bolt to the rock through a simple tensile test. In this case, the tension test apparatus is screwed to the threaded portion 222 formed in the injection unit body 220, and the lock bolt can be easily pulled out by tensioning the lock bolt using hydraulic pressure. .

In addition, with the lock bolt of the present invention installed in the tunnel, the cylindrical fastener (not shown) having a connection to the portion of the injection portion 120 formed with the thread 222 of the lock bolt exposed on the rock surface of the tunnel is screwed. Combined in a fastening method, and various accessory devices such as ventilation, electricity, lighting devices, etc. can be used as medals at the connection part of the end of the fixture.

As described above, the lock bolt of the present invention attaches a fastener having a connecting ring to a portion of the injection portion 120 of the lock bolt in which the thread 222 is formed in a state where the lock bolt is installed upward on the rock, and a fan to the connecting ring at the end of the fastener. In addition, there is an advantage that can be used to hang various additional devices, such as ventilation devices such as tunnels, tubes and lighting devices such as electric cables and electric lights.

At this time, the outer peripheral surface adjacent to the thread 222 of the injection unit body 220 may be formed with a circumferential groove 224, the circumferential groove 224 is a pressure fluid supply equipment is the injection unit 120 ) Is fastened to the groove 224 to be supported by a circular arc-shaped locking hole (not shown) provided in the pressure fluid supply equipment is stably coupled to the injection unit 120. To help maintain.

In addition, during construction of the lock bolt according to the present invention, the pressure plate 160 is inserted from the end of the expansion portion 100 located opposite the injection portion 120, the flange portion 226 formed at the end of the injection portion 120 Is supported.

Here, the mortar injection hole 162 may be formed at one side of the acupressure plate 160 to supply mortar into the boring hole into which the lock bolt is inserted when the lock bolt is installed. Since it is possible to supply the mortar into the inside of the drilling hole through which the lock bolt is inserted from the outside) there is no need to install a separate mortar injection hose in the internal space of the expansion unit (100).

8 is a view showing a coupling method of the injection unit 120 and the expansion unit 100 in the lock bolt structure of the present invention described above in sequence. 9 is a view illustrating a process of introducing a pressure fluid into the expansion part 100 through the injection part 120 of the lock bolt according to the present invention.

First, (a) of FIG. 8 illustrates an initial step of inserting the end of the expansion part 100 of the lock bolt into the injection part 120. Then, when the end of the expansion unit 100 through the step of (a) is inserted fully inserted to the end of the injection unit 120 as shown in (b) the folding unit 110 located inside the expansion unit 100 To be as straight as possible ("1"). Then, as shown in the arrow direction (W1) (W2) of (c) first weld the circular rim contacting the outer circumferential surface of the expansion portion 100 and the inner circumferential surface of the injection portion 120 and then the straight folding portion 110 portion Second welding When the welding is completed in this way, as shown in (d), the space between the expansion part 100 and the injection part 120 is sealed by the welding Z1, while the part of the folding part 110 is also sealed by the welding Z2 and the folding is performed. Two spaces in the shape of a semicircle in which pressure fluid is to be injected are formed at both left and right sides of the part 110. Lock bolts coupled using the method described above are formed with two semi-circular inner spaces inside the expansion part 100 viewed from the injection hole 221 side of the injection part 120, FIGS. 8E and 8. As shown in FIG. 9, the pressure fluid may be rapidly injected in parallel with the axial direction of the expansion part 100 through the injection hole 221 of the injection part 120.

As described above, the lock bolt of the present invention has a diameter (about 5 cm) in which the injection hole 221 of the lock bolt into which the pressure fluid is injected is approximately equal to the inner diameter of the injection part 120 or the expansion part 100. It is formed in a structure that is completely open at the end of the injection portion 120, the injection flow path of the pressure fluid from the injection hole 221 at the end of the injection portion 120 to the internal space 103 of the expansion portion 100 Since the level is horizontal, the pressure fluid can be easily introduced into the internal space of the expansion part when the pressure fluid is injected through the injection part 120 so that the lock bolt can be expanded quickly, and the installation time of the lock bolt can be increased. Can be shortened significantly.

In addition, in the lock bolt installed upward on the rock to be anchored, the pressure fluid remaining inside the lock bolt is naturally drained to the outside through the injection hole 221 opened at the end of the injection part 120 to completely discharge 100% of the pressure fluid. The drainage can be made, thereby preventing the corrosion phenomenon of the lock bolt caused by the residual pressure fluid in the lock bolt and the problem of lowering the fixing force due to the corrosion.

On the other hand, in the lock bolt of the present invention, the end of the expansion portion 100 located opposite the injection portion 120 is closed through the sealing portion 140. The sealing part 140 inserts the lock bolt into the drilled hole formed on the wall, so that even if the rock forming the drill hole is locally collapsed and the hole is partially blocked, the gap may be inserted and inserted forward. It is preferable to form a cone, a bullet, or a dome having an increasingly reduced cross section.

When the sealing unit 140 is coupled with the expansion unit 100, the end of the expansion unit 100 is inserted into the sealing unit 140, and then the sealing unit 140 and the expansion unit ( The outer edge where the 100 meets is welded to unite integrally.

In addition, in the lock bolt of the present invention, a vibration sensor (not shown) is installed in the expansion part 100 or the sealing part 140 of the lock bolt located in the drilling hole, and the electrical wiring extended from the vibration sensor is removed. When connected to an external output means (not shown) to express the safety abnormality, it is possible to detect the sign of collapse of the rock in advance in the blasting process for the tunnel or shaft excavation and to prevent a large accident accordingly.

In the case of including the vibration detection sensor, if the vibration detection sensor is installed in the expansion unit 100, there is a risk that the expansion unit 100 is crushed and broken between the rock during the expansion process, in this case relatively safe It may be configured to form a groove (not shown) in the sealing unit 140 and be installed in the form that the sensor is inserted into the groove.

Hereinafter, a process of stabilizing an excavation rock surface during tunnel or tunnel excavation performed through the expandable tubular lock bolt having the above-described configuration will be described in connection with the construction process of the lock bolt according to the present invention.

10 to 12 is a view schematically showing the construction process of the lock bolt according to an embodiment of the present invention, Figure 13 is a view showing a change in the cross-sectional shape of the lock bolt before and after the construction of the lock bolt construction in accordance with the present invention to be.

Reinforcement work for the rock to be carried out using the lock bolt according to the invention, the step of drilling a hole in the rock surface to be reinforced (Fig. 10), the step of inserting the lock bolt into the perforated hole (Fig. 11), and perforation Expanding and fixing the extension of the lock bolt located in the hole (FIG. 12).

First, in the step of punching the rock surface to be reinforced, as shown in Figure 10, the drilling of the rock is carried out using a conventional rock drill, the drilling direction is the excavation surface that can further enhance the effect of the lock bolt A direction perpendicular to is suitable.

At this time, the construction length of the drilling hole may be determined in consideration of various conditions such as physical properties of the rock, layered shape, etc. in consideration of the influence range due to excavation, and the extent to which the rock can be integrated by fixing the weak rock to a solid and stable rock Is enough.

When the drilling hole 202 is formed on the rock surface through the process of drilling holes in the rock as shown in FIG. 10, the expansion part 100 and the seal except the injection part 120 of the lock bolt 1 according to the present invention. Insert the lock bolt (1) so that the portion 140 is located in the drilling hole, and then the pressure fluid (300bar) to the expansion portion through the injection portion 120 using a separate pressure fluid supply equipment 30 as shown in FIG. High pressure water).

When the pressure fluid (high pressure water) is continuously introduced into the lock bolt 1 with the lock bolt 1 inserted in the drill hole 202, the expansion part 100 is expanded and the drill hole 202 is opened. The lock bolt 1 is fixed to the drilling hole 202 in a stable state by being in close contact with the rock surface to form (FIG. 12).

At this time, the expansion unit 100 located in the drilling hole 202 has a cross-sectional change as shown in FIG. 13 before and after expansion.

As such, when the expansion part 100 is expanded to fix the lock bolt 1 according to the present invention in the drilling hole 202, the pressure fluid supply equipment 30 is separated from the lock bolt 1. A simple tensile test tests the anchorage of the lock bolt against the rock.

If it is determined that sufficient lock bolt fixing force is secured, the lock bolt 1 is tensioned so that the pressure plate 160 exerts a compressive force on the base between the fixing unit and the pressure plate 160 to reinforce the ground. Construction is completed by preventing rockfall.

Here, since the lock bolt 1 is installed upward on the rock face in the case of a general tunnel or shaft excavation, the pressure fluid, for example, high pressure water, which has been injected to expand the expansion part 100, as shown in FIG. It is naturally discharged to the outside through the injection hole 120 formed parallel to the end of the injection portion 120. Therefore, no water remains in the lock bolt, and there is no fear of corrosion.

In addition, due to the protrusions 102 formed on the surface of the extension part 100 of the present invention, the protrusions 102 are caught by the rock edge of the fine pattern inside the drilling hole 202 during the expansion part 100 expansion. As a result of the strong resistance against the sliding of the lock bolt from slipping from the drill hole 202 immediately after construction, the lock bolt 1 is more firmly fixed to the drill hole 202 and more stable tensile force can be exerted. Can be.

On the other hand, another characteristic structure of the lock bolt according to the present invention is a configuration that can freely adjust the overall length of the lock bolt as needed.

15 is a partial perspective view illustrating a length expansion structure of a lock bolt by a connection member according to another embodiment of the present invention, and FIGS. 16 to 19 are angles of the lock bolt for implementing a lock bolt that can be extended in length. 20 and 21 are exemplary diagrams illustrating the extended length of the lock bolt by connecting the components illustrated in FIGS. 16 to 19.

Hereinafter, prior to describing the configuration of the lock bolt of the expandable length of the present invention, the same reference numerals and names are used for the same components as those of the above-described lock bolt components, and redundant description thereof will be omitted. .

Lock bolt according to the present invention is to extend the length of the lock bolt to a desired length by connecting a plurality of extension portion 100 of the above-described form in the longitudinal direction if the length extension is required. At this time, the connecting member is used as a component that connects the plurality of expansion parts 100 to each other in a line.

As shown in FIG. 15, the connection member includes a connector 310 coupled to an end of each expansion unit 100 connected to each other, and a sleeve 330 connecting between the connector 310.

In this case, when the connector 310 is coupled to the expansion unit 100, the connector 310 and the expansion unit 100 inserted into the connector 310 by inserting the ends of the expansion unit 100 into the connector 310 are formed. The outer edges of the meeting are welded together. In this case, male threads are formed on the outer circumferential surface of each connector 310 to be coupled to the sleeve 330 by a screwing method.

The sleeve 330 has a pipe shape, and a female screw portion corresponding to the male screw portion of the connector 310 is formed at inner ends of both ends of the partition 332 inside the central portion thereof. Such a sleeve 330 can be coupled to or separated from the connector 310 by screwing, and can extend the length of the lock bolt by connecting the plurality of expansion units 100 in a line through the sleeve 330. Will be.

FIG. 16 illustrates a product component including an injection part 120-an extension part 100-a connector 310 as one component for implementing a lock bolt which can be extended in length according to the present invention.

In the component of the lock bolt shown in FIG. 16, the coupling of the injection part 120 and the extension part 100 is performed by inserting one end of the extension part 100 into the injection part 120 as described in the above-described embodiment. After that, the inner peripheral surface of the injection unit 120 and the outer peripheral surface of the expansion unit 100 are joined to each other by welding.

In addition, the combination of the expansion unit 100 and the connector 310 is inserted into the other end of the expansion unit 100 into the connector 310, and then the expansion unit 100 and the connector 310 outside the meeting The edges are welded together.

In addition, FIG. 17 illustrates another component of the lock bolt interconnected with the above-described component of FIG. 16, and illustrates a product component including the connector 310-the extension 100-the connector 310.

As shown in FIG. 17, the connectors 310 are coupled to both ends of the extension part 100, and both ends of the extension part 100 are inserted into the respective connector parts 310, and then the extension part 100 and the extension part 100. Welding the outside of the edge where each connector 310 meets to manufacture integrally.

In addition, FIG. 18 illustrates a product composed of a connector 310-an extension 100-a sealing 140 as another component of the lock bolt interconnected with the aforementioned component of FIG. 17.

Coupling of the expansion unit 100 and the connector 310 in Figure 18 is in accordance with the coupling method described in Figures 16 and 17 described above. In addition, the expansion unit 100 and the sealing unit 140 are coupled to each other by inserting the ends of the expansion unit 100 into the sealing unit 140 and then the expansion unit 100 and the sealing unit 140 are It is produced by welding the outer edge of the meeting.

FIG. 21 is a cross-sectional view illustrating a connection structure between the connector 310 and the sleeve 330 of the expansion unit 100. When the plurality of product elements as shown in FIG. 17 are connected in a row, as shown in FIG. The connector 310 is connected to both ends of the 330 by screwing.

FIG. 20 illustrates an example in which the length of the lock bolt is extended by interconnecting the components shown in FIGS. 16 and 18 with one sleeve 330, and FIG. 21 is illustrated in FIGS. 16 to 18 described above. The illustrated component is shown by extending the length of the lock bolt by connecting through two sleeves (330).

As can be seen in Figures 20 and 21, the lock bolt of the present invention comprises a couple of injection-extension-connector, connector-expansion-connector, connector-extension-sealing, etc., which constitute the lock bolt described above. By connecting the two product elements through one or more sleeves 330 has the advantage that can be used to freely connect the lock bolt to the desired length.

That is, in the conventional lock bolt, the injection hole into which the pressure fluid is injected is formed at a very small size of about 1 mm at the side of the lock bolt, so that the initial injection direction of the pressure fluid through the injection hole is perpendicular to the longitudinal direction of the injection part or the expansion part. Since the lock bolt extends the length of the lock bolt, it is technically difficult to completely transfer the injection pressure of the pressure fluid to the end of the lock bolt where the seal is located. However, the lock bolt of the present invention is a pressure fluid. Is injected into the injection hole 120 or the expansion portion 100 is formed with a large diameter of about 5cm almost the same as the inner diameter of the injection portion 120, while the initial injection direction of the pressure fluid is parallel to the longitudinal direction of the injection portion or expansion portion When the length of the lock bolt is extended because the pressure fluid can be injected quickly at a large pressure within a short time. Also there is an advantage capable of transmitting pressure of the pressure fluid to the effective end of the rock bolt.

According to such a structure, the rock reinforcement work using a rock bolt having one expansion portion 100 as shown in FIG. In the case of rock or slope reinforcement in which the perforation hole is formed relatively deeply, reinforcement may be performed using a lock bolt having two or more extensions as shown in FIGS. 20 and 21.

As described above, the lock bolt of the present invention is not limited to the construction depth of the lock bolt because the lock bolt can freely extend the entire length of the lock bolt as needed by connecting two or more expansion parts 100 to each other. Rock reinforcement can be easily performed.

In addition, the vibration sensor is inserted through the injection hole 221 formed at the tip of the injection part 120 so as to be positioned inside the expansion part 100 or the sealing part 140, and connected to the vibration detection sensor. When the electrical wiring is connected to an external display means (not shown), it is possible to detect the sign of collapse of the rock in advance in the blasting process for the tunnel or the shaft excavation, thereby preventing a large accident.

What has been described above is only a few embodiments for carrying out the present invention, the present invention is not limited to the above embodiments, and as claimed in the following claims belong to the invention without departing from the gist of the invention. Anyone skilled in the art will have the technical scope of the present invention to the extent that various modifications can be made.

1 is a use state showing the installed state of the lock bolt according to the prior art.

Figure 2 is an exemplary view showing a coupling process of the steel tube and the injection portion of the lock bolt.

3 is an exemplary view illustrating a drainage process of a lock bolt installed upward in a tunnel.

Figure 4 is a perspective view showing a lock bolt structure according to an embodiment of the present invention.

5 is an exploded perspective view of FIG. 4.

6 is a cross-sectional view taken along the line A-A of FIG.

7 is a cross-sectional view taken along the line B-B of FIG.

8 is an exemplary view showing a coupling process by welding the expansion portion and the injection portion of the lock bolt according to the present invention.

Figure 9 is a use state showing the pressure fluid injection process through the injection portion of the lock bolt of the present invention.

10 to 12 schematically show a process in which the lock bolt according to the present invention is constructed upward.

Figure 13 is a view showing the cross-sectional shape change of the lock bolt before and after construction during construction of the lock bolt construction according to the present invention.

14 is an exemplary view illustrating a drainage process of a lock bolt installed upward in a tunnel.

15 is a perspective view showing a state in which the lock bolt of the present invention is connected through a connecting member.

Figure 16 is a schematic view of a product consisting of an inlet-extension-connector as a component of a lock bolt according to the invention.

Figure 17 is a schematic view of a product consisting of a connector-extension-connector as a component of a lock bolt according to the invention.

18 is a schematic view of a product consisting of a connector-extension-sealing as a component of a lock bolt according to the invention.

19 is a schematic view of a product consisting of a connector-sleeve-connector as a component of a lock bolt according to the invention.

20 illustrates an example in which the lengths of the lock bolts are extended by interconnecting the components shown in FIGS. 16 and 18 through one sleeve.

FIG. 21 shows an example in which the length of the lock bolt is extended by connecting the components shown in FIGS. 16 to 18 through two sleeves.

<Description of the symbols for the main parts of the drawings>

1: Lock bolt 30: Pressure fluid supply equipment

100: expansion portion 102: projection

120: injection portion 140: sealing portion

160: acupressure plate 110: folding part

162: mortar injection hole 202: drilling hole

220: body (injection part) 222: thread

221: injection hole 226: flange

310: connector 330: sleeve

Claims (12)

An inner space through which a pressure fluid can be introduced, and an extension portion having a tube shape having a folding portion formed by folding a portion of an outer surface inwardly; An injection unit coupled to one end of the expansion unit to communicate with an internal space of the expansion unit, into which pressure fluid supplied from a pressure fluid supply device is injected; It comprises a sealing part for sealing the other end of the expansion portion facing the injection portion, The folding part is formed to be folded in the form of a "(1)" to partition the inner space of the extension into two spaces of semi-circular shape, The injection portion is formed in the form of a pipe (pipe) with both ends open, the open end of the injection portion is connected to the expansion portion, the pressure fluid through the other open end of the injection portion axial direction of the injection portion Is injected into the configuration to be introduced into the internal space of the expansion, When the injection part and the expansion part are connected, a pressure fluid is formed by welding the circular edge portion and the straight folding part where the expansion part and the injection part meet in the state where the end of the expansion part is inserted into the open end of the injection part. An expandable tubular lock bolt, characterized in that configured to form two semicircular pressure fluid introduction space at the inlet portion of the expansion portion to be introduced. delete The method of claim 1, further comprising a pressure plate is inserted into the expansion portion supported on one end of the injection portion, And the mortar injection hole for injecting mortar is formed in the pressure plate. The expandable tubular lock bolt of claim 1, wherein a thread is formed on an outer surface of the injection portion. The expandable tubular lock bolt of claim 1, wherein a plurality of protrusions are formed on an outer surface of the extension part. The tubular lock bolt of claim 5, wherein the protrusion is irregularly arranged on an outer surface of the extension part. 6. The expandable tubular lock bolt according to claim 5, wherein the protrusion is formed on the outer surface of the extension portion in a helical shape along the longitudinal direction. 2. The expandable tubular lock bolt of claim 1 wherein the closure has a cone or bullet shaped contour and is integrally coupled to the end of the extension. 2. The expandable tubular lock bolt of claim 1 wherein the closure has a cone or bullet shape and is detachably coupled to the end of the extension by screwing. According to claim 1, wherein the expansion unit is provided with two or more are connected to each other in series through one or more connecting members, The connecting member, A connector that is coupled to an end of each of the expansion portions connected to each other and has a male screw portion formed on an outer surface thereof; And a male thread portion corresponding to the male portion of the connector and a female thread portion formed at each end thereof, the sleeve being coupled to the connector in a threaded manner. The expandable tubular lock bolt of claim 1, further comprising a vibration sensor mounted to the seal. The method of claim 11, wherein the vibration sensor, It is located in the lock bolt spaced apart from the construction, and expandable tubular type, characterized in that it is electrically connected to the output means for expressing the safety abnormality for the rock bolt construction rock by calculating the electrical signal applied from the vibration sensor Lock bolt.

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