KR20110048416A - Core drill using rock drilling - Google Patents

Abstract

PURPOSE: A core drill for drilling rocks is provided to remove a stone pillar by the generation of cracks on the outer surface of the stone pillar since a spike with a projection is formed on the contact part with the stone pillar. CONSTITUTION: A core drill for drilling rocks comprises a casing(104), a spike receiving member(200), a spike(210), and a core bit(110). A joint(102) is formed on one end of the casing. The casing is hollow and cylindrical to accept a punched stone pillar. The spike receiving member is a cylindrical hollow member positioned at the other end of the casing. One or more spike accepting grooves are formed along the inner circumference of the spike receiving member. The bottom of the spike is hinge-coupled within the spike accepting groove. The core bit is mounted at the end of the spike receiving member.

Description

Core Drill for Rock Drilling {CORE DRILL USING ROCK DRILLING}

The present invention relates to a core drill used for rock drilling, and more specifically, to a rock drill for core drilling to facilitate the removal of the stone formed inside the core drill after drilling by the core drill.

In general, for the foundation of the building works to install reinforcing work by installing a casing made of a steel pipe or the like on the soft ground, rock bed or the like. Particularly, when excavating a rock layer, severe vibration and noise are generated, and thus, there are many difficulties in working, such as frequent complaints due to civil complaints when excavating in urban areas.

To solve this problem, hammer bits of various configurations are provided. Representatively, combination hammers in which several hammers are combined with bits, a configuration in which an enlarged bit is formed at the outer periphery of the hammer, and a tricorn bit composed of three hemispherical bits are used.

In the case of the conventional hammer bits, there are many effects on vibration and noise, but many problems have been pointed out, such as excessively expensive construction costs, because the time required for excavation is low and the work time is long. Since a large-capacity high-pressure compressor should be used as a base, there are various problems such as high noise generation.

In order to solve this problem, a technique for greatly reducing the excavation of rock has been proposed. This is to excavate the rock in a ring shape to form a rock core in the center of the excavation surface. The core drill used here is to mount a drill tip made of artificial diamond in the lower end of the cylindrical casing in a ring shape, while rotating the cylindrical casing. The rock core of the maneuverable form is formed in the cylindrical casing at a constant length.

After drawing the core drill to the outside, the cylindrical rock core is blown and destroyed as a weight from the top to form an annular excavation surface into a circular rock hole, and the rock core piece placed on the rock hole is mounted on a crane or the like. As a grab facility to be mounted, the material is picked up, and then a core drilled ring is continuously formed in the rock hole to form one long rock hole sequentially.

However, such a conventional method greatly reduces the excavation area, but the excavation work speed is made quite fast, but it takes a long time to break the cylindrical rock core into a plurality of pieces and pull it out of the rock hole. In particular, the depth that can be excavated at one time as a core drill is approximately 500 mm or less in consideration of the work of removing the broken rock core, and thus there is a problem in that work productivity is reduced due to a long working time.

Therefore, the present invention is to solve the above-mentioned problems, install a spike receiving member formed with one or more spike receiving grooves along the inner circumferential surface between the casing and the core bit, and the upper end protrudes while the lower end is hinged in the spike receiving grooves. It is elastically supported so that the part of the upper part that comes into contact with the stone pillar in the forward rotation of the core drill is provided with spikes formed with protrusions to dig the stone stone to generate cracks on the outer circumferential surface of the stone stone stone formed during rock drilling to facilitate the stone stone An object of the present invention is to provide a core drill for rock drilling that can be removed.

In order to achieve the above and other objects of the present invention, according to an embodiment of the present invention, a core drill which is driven in the forward or reverse direction by a drive device and drills a rock, the coupling part is formed at one end and mounted to the drive device. A hollow-cylindrical casing for accommodating the stone pillars perforated from the rock, and a hollow-cylindrical member positioned at the other end of the casing, the spike receiving member having one or more spike receiving grooves formed along an inner circumferential surface thereof, and a lower end of the casing in the spike receiving groove. The hinge is elastically supported so that the upper end is protruded, the contact portion of the upper end of the core drill in the forward rotation of the spike is formed with a projection formed to dig the stone, and is mounted to the end of the spike receiving member to contact the rock The core drill for rock drilling, including the core bit It is.

The spikes are eccentrically hinged to one side of the spike receiving groove so as to be prevented from being rotated by being caught by one side wall of the core drill circumferential direction of the spike receiving groove during the reverse rotation of the core drill.

The protrusion of the spike includes several protrusions arranged in the circumferential direction of the core drill.

The spike receiving groove is preferably formed by penetrating the spike receiving member in the core drill radial direction.

A protrusion is formed on an inner circumferential surface of the casing at an interval over a predetermined distance above the spike receiving member.

The casing includes a sliding groove formed over a predetermined distance along the longitudinal direction of the casing at an upper predetermined position, and a sliding member installed in the sliding groove and slidingly moved along the longitudinal direction of the casing.

The sliding member may include a fixing nut installed on a bottom surface of the sliding groove, a lead screw having one end protruding upward from the sliding groove, and the other end rotatably fastened to the fixing nut, and penetratingly coupled to the lead screw. And a slide for sliding along the sliding groove as the lead screw rotates.

The sliding groove is formed such that one side of the inner circumferential surface is opened along the longitudinal direction of the casing, and guide grooves are formed on both inner side surfaces of the sliding groove so as to face each other.

The slide has a protrusion formed on one side to face the inner center of the casing, one side of the protrusion is preferably formed to be inclined from the top to the lower direction.

The lead screw is preferably formed so that it can be rotated using a tool.

According to the present invention having the above-described configuration, by installing a spike in the cylindrical groove formed in the rock drilling process to the receiving groove formed in the spy receiving member so that the spikes dig into the outer peripheral surface of the lower end of the stone cracks (Crack) There is an effect that can be easily removed by generating stone.

In addition, a sliding groove is formed in a predetermined position on the upper side of the casing over a predetermined distance along the longitudinal direction of the casing, and a sliding member which is slidably moved along the longitudinal direction of the casing is installed in the sliding groove to facilitate the masonry formed in a very hard rock. It can be removed.

Hereinafter, a rock drilling core drill according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a schematic view of a general rock drilling device, FIG. 2 is a perspective view of the core drill shown in FIG. 1, FIG. 3 is an exploded perspective view of the core drill shown in FIG. 2, and FIG. 4 is a core drill shown in FIG. 2. 5 is an exploded perspective view of the spike receiving member shown in FIG. 2, FIG. 6A is a longitudinal cross-sectional view of the sliding member according to the embodiment of the present invention, and FIG. 6B is a plan view of the sliding member shown in FIG. 6A. 7 is an operational state diagram of the spike shown in FIG. 5, FIG. 8 is a perspective view of the core bit shown in FIG. 1, FIG. 9 is an exploded perspective view showing a modified embodiment of the spike receiving member, and FIG. 9 is an operational state diagram of the spike shown in FIG.

2 and 8, the core drill 100 for rock drilling according to the embodiment of the present invention is driven in the forward or reverse direction by the driving device 10 and is a core drill 100 for drilling the rock. Spike receiving member 120 having a coupling portion 102 is formed in the casing 104 is mounted to the drive device, and the other end of the casing 104 and at least one spike receiving groove 202 is formed along the inner peripheral surface And, the lower portion is hinged in the spike receiving groove 202, the portion in contact with the stone spike (210) formed with a projection 212 to dig the stone, and the end of the spike receiving member 120 to contact the rock It includes a core bit 110 to be mounted.

The casing 104 is of a hollow cylinder type, and a coupling portion 102 is formed at one end thereof, and is mounted to the driving device 10 to accommodate the masonry drilled from the rock.

In addition, referring to FIG. 4, the casing 104 is provided at a sliding groove 302 formed over a predetermined distance along a longitudinal direction of the casing 104 at an upper predetermined position, and is installed at the sliding groove 302 so that the casing ( And a sliding member 300 which is slid along the longitudinal direction of the 104.

The sliding groove 302 is formed such that one side of the inner circumferential surface is opened along the longitudinal direction of the casing 104, and guide grooves 304 are formed on both inner sides of the casing 104 to face each other.

The guide groove 304 is coupled with the slide protrusions 308 formed on both sides of the slide 306 to be described later to prevent the slide 306 from being separated from the guide groove 304 when the slide 306 is vertically sliding. do.

The sliding member 300 has a fixing nut 310 installed on the bottom surface of the sliding groove 302, one end thereof protrudes above the sliding groove 302, and the other end is rotatable to the fixing nut 310. And a slide 306 sliding through the sliding groove 302 as the lead screw 312 rotates through the lead screw 312 and the lead screw 312 is rotated.

The slide 306 has a protrusion 314 formed at one side to face the inner center of the casing 104, and one side of the protrusion 314 is formed to be inclined from the upper side to the lower side.

In addition, it is preferable that slide projections 308 are formed on both side surfaces of the slide 306 so as to correspond to the aforementioned guide grooves 304.

Here, according to a modified embodiment of the present invention, guide protrusions may be formed on the sliding grooves 302 so as to face each other on both inner surfaces along the longitudinal direction of the casing 104, and slide grooves may be formed on both sides of the slide 306. have.

The lead screw 312 is formed with a polygonal head portion 316 at one end to be rotated using a tool.

Therefore, as described above, in order to remove the stone pillar formed in the core drill 100 after the rock drilling, the head portion 316 formed at one end of the lead screw 312 is rotated in one direction using a tool such as a wrench. The lead screw 312 rotates, and as the lead screw 312 rotates, the slide 306 also moves up and down.

At this time, when the slide 306 is moved in the downward direction, the protrusion 314 formed on one side of the slide 306 gradually moves downward while pressing the outer circumferential surface of the stone to press the stone in one direction, the protrusion 314 The incline inclined in one direction by) causes cracks to break at the lower end thereof.

The spike receiving member 200 is a hollow cylindrical member which is coupled to the other end of the casing 104 by welding or the like.

Referring to FIG. 5, the spike receiving member 200 includes one or more spike receiving grooves 202 formed along an inner circumferential surface to accommodate the spike 210 to be described later, and the spike receiving groove 202 is the spike. The core drill 100 of the receiving member 200 is formed to penetrate in the radial direction.

Here, fastening holes 204 are formed on both side walls of the spike receiving groove 202, that is, in the longitudinal direction of the spike receiving member 200.

The spike 210 has a protrusion 212 formed so as to dig the stone in the portion in contact with the stone so as to apply a large pressure to the outer peripheral surface of the perforated stone, the protrusion 212 is a number that is arranged in the circumferential direction of the core drill 100 Includes dog projections.

The spike 210 is elastically supported so that the upper end is protruded while the lower end is hinged to the fastening hole 204 formed on both side walls of the spike receiving groove 202.

Here, one end is supported on one side of the spike 210 to elastically support the spike 210 by hinge-bonding the hinge pin 208 inside the spike receiving groove 202 so that the upper end thereof protrudes, and the other end. It is preferable that the elastic member 206 is supported on one side of the spike receiving groove 202. The elastic member 206 is preferably a compression coil spring.

In addition, in installing the elastic member 206, the other end portion of the elastic member on one side of the spike receiving groove 202, although not shown in the drawing may be formed in the support groove to be accommodated and supported.

The spike 210 is eccentrically hinged to one side of the spike receiving groove 202 so that rotation is suppressed by being caught by one circumferential wall of the core drill 100 of the spike receiving groove 202 during the reverse rotation of the core drill 100. Combined.

Here, referring to FIG. 7, the spike 210 is accommodated in the spike receiving groove 202 when the core drill 100 rotates in the forward direction, and the elastic member 206 when the core drill 100 rotates in the reverse direction. The projections of the protrusions 212 formed in the portion contacting the stone to gradually dig the outer circumferential surface of the stone by the elastic force of the preferably is formed so that the height of the protrusion gradually from the portion in contact with the stone.

The core bit 110 is mounted at the end of the spike receiving member and makes contact with the rock to form perforations in the rock.

Meanwhile, referring to FIG. 4, protrusions 106 are formed on the inner circumferential surface at predetermined intervals over a predetermined distance above the spike receiving member 200 of the casing 104, and the protrusions 106 are parts such as bolts and the like. It is installed by a method such as welding.

Here, the inner diameter D ₁ of the casing 104 is smaller than the inner diameter D ₂ of the spike receiving member 200, and the inner diameter D ₁ of the casing 104 and the inner diameter of the spike receiving member 200 ( The above-mentioned protrusion 106 is formed between D ₂ ).

Meanwhile, according to another embodiment of the present invention, as shown in FIGS. 9 and 10, the spike receiving member 400 may include at least one first spike receiving groove 402 formed at a predetermined interval along an inner circumferential surface thereof, and It includes a second spike receiving groove 404 formed between the first spike receiving grooves 402, and is a hollow cylindrical member coupled to the other end of the casing 104 by welding or the like.

9 and 10, the first and second spike receiving grooves 402 and 404 are formed to penetrate in the radial direction of the core drill 100 of the spike receiving member 400. The second spikes 410 and 420 are received.

Here, fastening holes (not shown) are formed on both side walls of the first spike receiving groove 402, that is, in the longitudinal direction of the spike receiving member 400.

The first spike 410 is a cam-shaped member in which the pressing portion 412 is formed at one side to dig the masonry so as to apply a large pressure to the outer circumferential surface of the perforated masonry.

The first spike 410 is elastically supported so that the upper end is protruded while the lower end is hinged to a fastening hole (not shown) formed in both side walls of the first spike receiving groove 402.

Here, one end is supported on one side of the first spike 410 so that the first spike 410 is hinged to the first spike receiving groove 402 to elastically support the upper end to protrude, and the other end is It is preferable that the elastic member 206 supported on one side of the first spike receiving groove 402 is installed. The elastic member 206 is preferably a compression coil spring.

The second spike receiving groove 404 is formed concave along the circumferential direction of the core drill 100, the upper surface of the second spike receiving groove 404 on one side so that the second spike 420 to be described later is coupled A plurality of first coupling holes 406 are formed.

The second spike 420 includes a rectangular spike connecting member 422. The spike connecting member 422 has a second coupling hole 408 is formed on one side corresponding to the first coupling hole 406 to be coupled to the second spike receiving groove 404, the spike connecting member ( 422 is coupled to the second spike receiving groove 404 using bolts 414.

The second spike 420 is a cam-shaped member in which the pressing portion 412 is formed at one side to dig the masonry so as to apply a large pressure to the outer circumferential surface of the perforated masonry.

The second spike 420 is elastically supported such that its lower end protrudes while being hinged to the fastening holes 416 formed on both side walls of the spike connecting member 422.

Here, the second spike 420 is hinged to the fastening hole 416 formed in the spike connecting member 422 through the hinge pin 418, one end of the second spike ( It is preferable that the elastic member 206 is supported on one side of the 420, the other end is supported on one side of the spike connecting member 422. The elastic member 206 is preferably a compression coil spring.

While the preferred embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art may variously modify and change the present invention without departing from the spirit of the invention described in the claims below. It will be appreciated.

1 is a schematic diagram of a typical rock perforation device.

Figure 2 is a perspective view of the core drill shown in FIG.

3 is an exploded perspective view of the core drill shown in FIG.

4 is a longitudinal sectional view of the core drill shown in FIG.

5 is an exploded perspective view of the spike receiving member shown in FIG.

6A is a longitudinal cross-sectional view of a sliding member according to an embodiment of the present invention.

6B is a plan view of the sliding member shown in FIG. 6A.

7 is an operating state diagram of the spike shown in FIG.

8 is a perspective view of the core bit shown in FIG.

9 is an exploded perspective view showing a modified embodiment of the spike receiving member.

10 is an operating state diagram of the spike shown in FIG.

<Description of reference numerals for the main parts of the drawings>

10: drive device 402: first spike receiving groove

100: coredrill 404: second spike receiving groove

102: coupling portion 406: first coupling hole

104: casing 408: second coupling hole

106: protrusion 410: first spike

110: core bit 412: pressing portion

200, 400: spike receiving member 414: bolt

202: spike receiving groove 420: second spike

204, 416: fastening hole 422: spike connecting member

206: elastic member

208, 418: hinge pins

210: spikes

212: protrusion

300: sliding member

302: sliding groove

304: guide groove

306: slide

308: slide projection

310: fixing nut

312: lead screw

314: protrusion

Claims (10)

A core drill driven in a forward or reverse direction by a drive device and drilling a rock, A hollow casing-shaped casing configured at one end thereof to be mounted to the driving device and accommodating the stone pillars perforated from the rock; A hollow park cylindrical member positioned at the other end of the casing, the spike receiving member having one or more spike receiving grooves formed along an inner circumferential surface thereof; A lower end is hinged into the spike receiving groove and is elastically supported to protrude from the upper end, and a part of the upper end contacting the stone pillar in the reverse rotation of the core drill includes a spike having a protrusion formed to dig the stone; A core drill for drilling bores, comprising a core bit mounted to the end of the spike receiving member to contact the rock. The method of claim 1, And the spikes are eccentrically hinged to one side of the spike receiving groove so as to be prevented from being rotated by being caught by one side wall of the core drill circumferential direction of the spike receiving groove during the reverse rotation of the core drill. The method of claim 1, The projections of the spikes rock drilling core drill characterized in that it comprises a plurality of projections arranged in the circumferential direction of the core drill. The method of claim 1, The spike receiving groove is a rock drilling core drill, characterized in that formed through the core drill radial direction of the spike receiving member. The method of claim 1, The core drill for rock drilling, characterized in that the projection formed on the inner peripheral surface at a predetermined interval over a predetermined distance on the spike receiving member of the casing. The method of claim 1, wherein the casing, And a sliding groove formed at an upper predetermined position over a predetermined distance along a longitudinal direction of the casing, and a sliding member installed in the sliding groove to slide in a longitudinal direction of the casing. The method of claim 6, wherein the sliding member, A fixing nut installed on the bottom surface of the sliding groove, a lead screw having one end protruding upward of the sliding groove, and the other end rotatably fastened to the fixing nut, and a lead screw rotating through the lead screw The core drill for rock drilling, characterized in that it comprises a slide for sliding along the sliding groove. The method of claim 6, The sliding groove is formed so that one side of the inner circumferential surface is opened along the longitudinal direction of the casing, guide holes are formed on both sides of the inner surface in the longitudinal direction of the casing to face each other. The method of claim 7, wherein The slide has a protrusion formed on one side toward the inner center of the casing, the core drill for rock drilling, characterized in that one side of the protrusion is formed to be inclined in the downward direction from the top. The method of claim 7, wherein The lead screw is a core drilling core drill, characterized in that the polygonal head portion is formed at one end to be rotated using a tool.

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